WSL2-Linux-Kernel/drivers/media/dvb-frontends/dib8000.c

4509 строки
133 KiB
C
Исходник Обычный вид История

// SPDX-License-Identifier: GPL-2.0-only
/*
* Linux-DVB Driver for DiBcom's DiB8000 chip (ISDB-T).
*
* Copyright (C) 2009 DiBcom (http://www.dibcom.fr/)
*/
#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
#include <linux/kernel.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 11:04:11 +03:00
#include <linux/slab.h>
#include <linux/i2c.h>
#include <linux/mutex.h>
#include <asm/div64.h>
#include <media/dvb_math.h>
#include <media/dvb_frontend.h>
#include "dib8000.h"
#define LAYER_ALL -1
#define LAYER_A 1
#define LAYER_B 2
#define LAYER_C 3
#define MAX_NUMBER_OF_FRONTENDS 6
/* #define DIB8000_AGC_FREEZE */
static int debug;
module_param(debug, int, 0644);
MODULE_PARM_DESC(debug, "turn on debugging (default: 0)");
#define dprintk(fmt, arg...) do { \
if (debug) \
printk(KERN_DEBUG pr_fmt("%s: " fmt), \
__func__, ##arg); \
} while (0)
struct i2c_device {
struct i2c_adapter *adap;
u8 addr;
u8 *i2c_write_buffer;
u8 *i2c_read_buffer;
struct mutex *i2c_buffer_lock;
};
enum param_loop_step {
LOOP_TUNE_1,
LOOP_TUNE_2
};
enum dib8000_autosearch_step {
AS_START = 0,
AS_SEARCHING_FFT,
AS_SEARCHING_GUARD,
AS_DONE = 100,
};
enum timeout_mode {
SYMBOL_DEPENDENT_OFF = 0,
SYMBOL_DEPENDENT_ON,
};
struct dib8000_state {
struct dib8000_config cfg;
struct i2c_device i2c;
struct dibx000_i2c_master i2c_master;
u16 wbd_ref;
u8 current_band;
u32 current_bandwidth;
struct dibx000_agc_config *current_agc;
u32 timf;
u32 timf_default;
u8 div_force_off:1;
u8 div_state:1;
u16 div_sync_wait;
u8 agc_state;
u8 differential_constellation;
u8 diversity_onoff;
s16 ber_monitored_layer;
u16 gpio_dir;
u16 gpio_val;
u16 revision;
u8 isdbt_cfg_loaded;
enum frontend_tune_state tune_state;
s32 status;
struct dvb_frontend *fe[MAX_NUMBER_OF_FRONTENDS];
/* for the I2C transfer */
struct i2c_msg msg[2];
u8 i2c_write_buffer[4];
u8 i2c_read_buffer[2];
struct mutex i2c_buffer_lock;
u8 input_mode_mpeg;
u16 tuner_enable;
struct i2c_adapter dib8096p_tuner_adap;
u16 current_demod_bw;
u16 seg_mask;
u16 seg_diff_mask;
u16 mode;
u8 layer_b_nb_seg;
u8 layer_c_nb_seg;
u8 channel_parameters_set;
u16 autosearch_state;
u16 found_nfft;
u16 found_guard;
u8 subchannel;
u8 symbol_duration;
unsigned long timeout;
u8 longest_intlv_layer;
u16 output_mode;
/* for DVBv5 stats */
s64 init_ucb;
unsigned long per_jiffies_stats;
unsigned long ber_jiffies_stats;
unsigned long ber_jiffies_stats_layer[3];
#ifdef DIB8000_AGC_FREEZE
u16 agc1_max;
u16 agc1_min;
u16 agc2_max;
u16 agc2_min;
#endif
};
enum dib8000_power_mode {
DIB8000_POWER_ALL = 0,
DIB8000_POWER_INTERFACE_ONLY,
};
static u16 dib8000_i2c_read16(struct i2c_device *i2c, u16 reg)
{
u16 ret;
struct i2c_msg msg[2] = {
{.addr = i2c->addr >> 1, .flags = 0, .len = 2},
{.addr = i2c->addr >> 1, .flags = I2C_M_RD, .len = 2},
};
if (mutex_lock_interruptible(i2c->i2c_buffer_lock) < 0) {
dprintk("could not acquire lock\n");
return 0;
}
msg[0].buf = i2c->i2c_write_buffer;
msg[0].buf[0] = reg >> 8;
msg[0].buf[1] = reg & 0xff;
msg[1].buf = i2c->i2c_read_buffer;
if (i2c_transfer(i2c->adap, msg, 2) != 2)
dprintk("i2c read error on %d\n", reg);
ret = (msg[1].buf[0] << 8) | msg[1].buf[1];
mutex_unlock(i2c->i2c_buffer_lock);
return ret;
}
static u16 __dib8000_read_word(struct dib8000_state *state, u16 reg)
{
u16 ret;
state->i2c_write_buffer[0] = reg >> 8;
state->i2c_write_buffer[1] = reg & 0xff;
memset(state->msg, 0, 2 * sizeof(struct i2c_msg));
state->msg[0].addr = state->i2c.addr >> 1;
state->msg[0].flags = 0;
state->msg[0].buf = state->i2c_write_buffer;
state->msg[0].len = 2;
state->msg[1].addr = state->i2c.addr >> 1;
state->msg[1].flags = I2C_M_RD;
state->msg[1].buf = state->i2c_read_buffer;
state->msg[1].len = 2;
if (i2c_transfer(state->i2c.adap, state->msg, 2) != 2)
dprintk("i2c read error on %d\n", reg);
ret = (state->i2c_read_buffer[0] << 8) | state->i2c_read_buffer[1];
return ret;
}
static u16 dib8000_read_word(struct dib8000_state *state, u16 reg)
{
u16 ret;
if (mutex_lock_interruptible(&state->i2c_buffer_lock) < 0) {
dprintk("could not acquire lock\n");
return 0;
}
ret = __dib8000_read_word(state, reg);
mutex_unlock(&state->i2c_buffer_lock);
return ret;
}
static u32 dib8000_read32(struct dib8000_state *state, u16 reg)
{
u16 rw[2];
if (mutex_lock_interruptible(&state->i2c_buffer_lock) < 0) {
dprintk("could not acquire lock\n");
return 0;
}
rw[0] = __dib8000_read_word(state, reg + 0);
rw[1] = __dib8000_read_word(state, reg + 1);
mutex_unlock(&state->i2c_buffer_lock);
return ((rw[0] << 16) | (rw[1]));
}
static int dib8000_i2c_write16(struct i2c_device *i2c, u16 reg, u16 val)
{
struct i2c_msg msg = {.addr = i2c->addr >> 1, .flags = 0, .len = 4};
int ret = 0;
if (mutex_lock_interruptible(i2c->i2c_buffer_lock) < 0) {
dprintk("could not acquire lock\n");
return -EINVAL;
}
msg.buf = i2c->i2c_write_buffer;
msg.buf[0] = (reg >> 8) & 0xff;
msg.buf[1] = reg & 0xff;
msg.buf[2] = (val >> 8) & 0xff;
msg.buf[3] = val & 0xff;
ret = i2c_transfer(i2c->adap, &msg, 1) != 1 ? -EREMOTEIO : 0;
mutex_unlock(i2c->i2c_buffer_lock);
return ret;
}
static int dib8000_write_word(struct dib8000_state *state, u16 reg, u16 val)
{
int ret;
if (mutex_lock_interruptible(&state->i2c_buffer_lock) < 0) {
dprintk("could not acquire lock\n");
return -EINVAL;
}
state->i2c_write_buffer[0] = (reg >> 8) & 0xff;
state->i2c_write_buffer[1] = reg & 0xff;
state->i2c_write_buffer[2] = (val >> 8) & 0xff;
state->i2c_write_buffer[3] = val & 0xff;
memset(&state->msg[0], 0, sizeof(struct i2c_msg));
state->msg[0].addr = state->i2c.addr >> 1;
state->msg[0].flags = 0;
state->msg[0].buf = state->i2c_write_buffer;
state->msg[0].len = 4;
ret = (i2c_transfer(state->i2c.adap, state->msg, 1) != 1 ?
-EREMOTEIO : 0);
mutex_unlock(&state->i2c_buffer_lock);
return ret;
}
static const s16 coeff_2k_sb_1seg_dqpsk[8] = {
(769 << 5) | 0x0a, (745 << 5) | 0x03, (595 << 5) | 0x0d, (769 << 5) | 0x0a, (920 << 5) | 0x09, (784 << 5) | 0x02, (519 << 5) | 0x0c,
(920 << 5) | 0x09
};
static const s16 coeff_2k_sb_1seg[8] = {
(692 << 5) | 0x0b, (683 << 5) | 0x01, (519 << 5) | 0x09, (692 << 5) | 0x0b, 0 | 0x1f, 0 | 0x1f, 0 | 0x1f, 0 | 0x1f
};
static const s16 coeff_2k_sb_3seg_0dqpsk_1dqpsk[8] = {
(832 << 5) | 0x10, (912 << 5) | 0x05, (900 << 5) | 0x12, (832 << 5) | 0x10, (-931 << 5) | 0x0f, (912 << 5) | 0x04, (807 << 5) | 0x11,
(-931 << 5) | 0x0f
};
static const s16 coeff_2k_sb_3seg_0dqpsk[8] = {
(622 << 5) | 0x0c, (941 << 5) | 0x04, (796 << 5) | 0x10, (622 << 5) | 0x0c, (982 << 5) | 0x0c, (519 << 5) | 0x02, (572 << 5) | 0x0e,
(982 << 5) | 0x0c
};
static const s16 coeff_2k_sb_3seg_1dqpsk[8] = {
(699 << 5) | 0x14, (607 << 5) | 0x04, (944 << 5) | 0x13, (699 << 5) | 0x14, (-720 << 5) | 0x0d, (640 << 5) | 0x03, (866 << 5) | 0x12,
(-720 << 5) | 0x0d
};
static const s16 coeff_2k_sb_3seg[8] = {
(664 << 5) | 0x0c, (925 << 5) | 0x03, (937 << 5) | 0x10, (664 << 5) | 0x0c, (-610 << 5) | 0x0a, (697 << 5) | 0x01, (836 << 5) | 0x0e,
(-610 << 5) | 0x0a
};
static const s16 coeff_4k_sb_1seg_dqpsk[8] = {
(-955 << 5) | 0x0e, (687 << 5) | 0x04, (818 << 5) | 0x10, (-955 << 5) | 0x0e, (-922 << 5) | 0x0d, (750 << 5) | 0x03, (665 << 5) | 0x0f,
(-922 << 5) | 0x0d
};
static const s16 coeff_4k_sb_1seg[8] = {
(638 << 5) | 0x0d, (683 << 5) | 0x02, (638 << 5) | 0x0d, (638 << 5) | 0x0d, (-655 << 5) | 0x0a, (517 << 5) | 0x00, (698 << 5) | 0x0d,
(-655 << 5) | 0x0a
};
static const s16 coeff_4k_sb_3seg_0dqpsk_1dqpsk[8] = {
(-707 << 5) | 0x14, (910 << 5) | 0x06, (889 << 5) | 0x16, (-707 << 5) | 0x14, (-958 << 5) | 0x13, (993 << 5) | 0x05, (523 << 5) | 0x14,
(-958 << 5) | 0x13
};
static const s16 coeff_4k_sb_3seg_0dqpsk[8] = {
(-723 << 5) | 0x13, (910 << 5) | 0x05, (777 << 5) | 0x14, (-723 << 5) | 0x13, (-568 << 5) | 0x0f, (547 << 5) | 0x03, (696 << 5) | 0x12,
(-568 << 5) | 0x0f
};
static const s16 coeff_4k_sb_3seg_1dqpsk[8] = {
(-940 << 5) | 0x15, (607 << 5) | 0x05, (915 << 5) | 0x16, (-940 << 5) | 0x15, (-848 << 5) | 0x13, (683 << 5) | 0x04, (543 << 5) | 0x14,
(-848 << 5) | 0x13
};
static const s16 coeff_4k_sb_3seg[8] = {
(612 << 5) | 0x12, (910 << 5) | 0x04, (864 << 5) | 0x14, (612 << 5) | 0x12, (-869 << 5) | 0x13, (683 << 5) | 0x02, (869 << 5) | 0x12,
(-869 << 5) | 0x13
};
static const s16 coeff_8k_sb_1seg_dqpsk[8] = {
(-835 << 5) | 0x12, (684 << 5) | 0x05, (735 << 5) | 0x14, (-835 << 5) | 0x12, (-598 << 5) | 0x10, (781 << 5) | 0x04, (739 << 5) | 0x13,
(-598 << 5) | 0x10
};
static const s16 coeff_8k_sb_1seg[8] = {
(673 << 5) | 0x0f, (683 << 5) | 0x03, (808 << 5) | 0x12, (673 << 5) | 0x0f, (585 << 5) | 0x0f, (512 << 5) | 0x01, (780 << 5) | 0x0f,
(585 << 5) | 0x0f
};
static const s16 coeff_8k_sb_3seg_0dqpsk_1dqpsk[8] = {
(863 << 5) | 0x17, (930 << 5) | 0x07, (878 << 5) | 0x19, (863 << 5) | 0x17, (0 << 5) | 0x14, (521 << 5) | 0x05, (980 << 5) | 0x18,
(0 << 5) | 0x14
};
static const s16 coeff_8k_sb_3seg_0dqpsk[8] = {
(-924 << 5) | 0x17, (910 << 5) | 0x06, (774 << 5) | 0x17, (-924 << 5) | 0x17, (-877 << 5) | 0x15, (565 << 5) | 0x04, (553 << 5) | 0x15,
(-877 << 5) | 0x15
};
static const s16 coeff_8k_sb_3seg_1dqpsk[8] = {
(-921 << 5) | 0x19, (607 << 5) | 0x06, (881 << 5) | 0x19, (-921 << 5) | 0x19, (-921 << 5) | 0x14, (713 << 5) | 0x05, (1018 << 5) | 0x18,
(-921 << 5) | 0x14
};
static const s16 coeff_8k_sb_3seg[8] = {
(514 << 5) | 0x14, (910 << 5) | 0x05, (861 << 5) | 0x17, (514 << 5) | 0x14, (690 << 5) | 0x14, (683 << 5) | 0x03, (662 << 5) | 0x15,
(690 << 5) | 0x14
};
static const s16 ana_fe_coeff_3seg[24] = {
81, 80, 78, 74, 68, 61, 54, 45, 37, 28, 19, 11, 4, 1022, 1017, 1013, 1010, 1008, 1008, 1008, 1008, 1010, 1014, 1017
};
static const s16 ana_fe_coeff_1seg[24] = {
249, 226, 164, 82, 5, 981, 970, 988, 1018, 20, 31, 26, 8, 1012, 1000, 1018, 1012, 8, 15, 14, 9, 3, 1017, 1003
};
static const s16 ana_fe_coeff_13seg[24] = {
396, 305, 105, -51, -77, -12, 41, 31, -11, -30, -11, 14, 15, -2, -13, -7, 5, 8, 1, -6, -7, -3, 0, 1
};
static u16 fft_to_mode(struct dib8000_state *state)
{
u16 mode;
switch (state->fe[0]->dtv_property_cache.transmission_mode) {
case TRANSMISSION_MODE_2K:
mode = 1;
break;
case TRANSMISSION_MODE_4K:
mode = 2;
break;
default:
case TRANSMISSION_MODE_AUTO:
case TRANSMISSION_MODE_8K:
mode = 3;
break;
}
return mode;
}
static void dib8000_set_acquisition_mode(struct dib8000_state *state)
{
u16 nud = dib8000_read_word(state, 298);
nud |= (1 << 3) | (1 << 0);
dprintk("acquisition mode activated\n");
dib8000_write_word(state, 298, nud);
}
static int dib8000_set_output_mode(struct dvb_frontend *fe, int mode)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 outreg, fifo_threshold, smo_mode, sram = 0x0205; /* by default SDRAM deintlv is enabled */
state->output_mode = mode;
outreg = 0;
fifo_threshold = 1792;
smo_mode = (dib8000_read_word(state, 299) & 0x0050) | (1 << 1);
dprintk("-I- Setting output mode for demod %p to %d\n",
&state->fe[0], mode);
switch (mode) {
case OUTMODE_MPEG2_PAR_GATED_CLK: // STBs with parallel gated clock
outreg = (1 << 10); /* 0x0400 */
break;
case OUTMODE_MPEG2_PAR_CONT_CLK: // STBs with parallel continues clock
outreg = (1 << 10) | (1 << 6); /* 0x0440 */
break;
case OUTMODE_MPEG2_SERIAL: // STBs with serial input
outreg = (1 << 10) | (2 << 6) | (0 << 1); /* 0x0482 */
break;
case OUTMODE_DIVERSITY:
if (state->cfg.hostbus_diversity) {
outreg = (1 << 10) | (4 << 6); /* 0x0500 */
sram &= 0xfdff;
} else
sram |= 0x0c00;
break;
case OUTMODE_MPEG2_FIFO: // e.g. USB feeding
smo_mode |= (3 << 1);
fifo_threshold = 512;
outreg = (1 << 10) | (5 << 6);
break;
case OUTMODE_HIGH_Z: // disable
outreg = 0;
break;
case OUTMODE_ANALOG_ADC:
outreg = (1 << 10) | (3 << 6);
dib8000_set_acquisition_mode(state);
break;
default:
dprintk("Unhandled output_mode passed to be set for demod %p\n",
&state->fe[0]);
return -EINVAL;
}
if (state->cfg.output_mpeg2_in_188_bytes)
smo_mode |= (1 << 5);
dib8000_write_word(state, 299, smo_mode);
dib8000_write_word(state, 300, fifo_threshold); /* synchronous fread */
dib8000_write_word(state, 1286, outreg);
dib8000_write_word(state, 1291, sram);
return 0;
}
static int dib8000_set_diversity_in(struct dvb_frontend *fe, int onoff)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 tmp, sync_wait = dib8000_read_word(state, 273) & 0xfff0;
dprintk("set diversity input to %i\n", onoff);
if (!state->differential_constellation) {
dib8000_write_word(state, 272, 1 << 9); //dvsy_off_lmod4 = 1
dib8000_write_word(state, 273, sync_wait | (1 << 2) | 2); // sync_enable = 1; comb_mode = 2
} else {
dib8000_write_word(state, 272, 0); //dvsy_off_lmod4 = 0
dib8000_write_word(state, 273, sync_wait); // sync_enable = 0; comb_mode = 0
}
state->diversity_onoff = onoff;
switch (onoff) {
case 0: /* only use the internal way - not the diversity input */
dib8000_write_word(state, 270, 1);
dib8000_write_word(state, 271, 0);
break;
case 1: /* both ways */
dib8000_write_word(state, 270, 6);
dib8000_write_word(state, 271, 6);
break;
case 2: /* only the diversity input */
dib8000_write_word(state, 270, 0);
dib8000_write_word(state, 271, 1);
break;
}
if (state->revision == 0x8002) {
tmp = dib8000_read_word(state, 903);
dib8000_write_word(state, 903, tmp & ~(1 << 3));
msleep(30);
dib8000_write_word(state, 903, tmp | (1 << 3));
}
return 0;
}
static void dib8000_set_power_mode(struct dib8000_state *state, enum dib8000_power_mode mode)
{
/* by default everything is going to be powered off */
u16 reg_774 = 0x3fff, reg_775 = 0xffff, reg_776 = 0xffff,
reg_900 = (dib8000_read_word(state, 900) & 0xfffc) | 0x3,
reg_1280;
if (state->revision != 0x8090)
reg_1280 = (dib8000_read_word(state, 1280) & 0x00ff) | 0xff00;
else
reg_1280 = (dib8000_read_word(state, 1280) & 0x707f) | 0x8f80;
/* now, depending on the requested mode, we power on */
switch (mode) {
/* power up everything in the demod */
case DIB8000_POWER_ALL:
reg_774 = 0x0000;
reg_775 = 0x0000;
reg_776 = 0x0000;
reg_900 &= 0xfffc;
if (state->revision != 0x8090)
reg_1280 &= 0x00ff;
else
reg_1280 &= 0x707f;
break;
case DIB8000_POWER_INTERFACE_ONLY:
if (state->revision != 0x8090)
reg_1280 &= 0x00ff;
else
reg_1280 &= 0xfa7b;
break;
}
dprintk("powermode : 774 : %x ; 775 : %x; 776 : %x ; 900 : %x; 1280 : %x\n", reg_774, reg_775, reg_776, reg_900, reg_1280);
dib8000_write_word(state, 774, reg_774);
dib8000_write_word(state, 775, reg_775);
dib8000_write_word(state, 776, reg_776);
dib8000_write_word(state, 900, reg_900);
dib8000_write_word(state, 1280, reg_1280);
}
static int dib8000_set_adc_state(struct dib8000_state *state, enum dibx000_adc_states no)
{
int ret = 0;
u16 reg, reg_907 = dib8000_read_word(state, 907);
u16 reg_908 = dib8000_read_word(state, 908);
switch (no) {
case DIBX000_SLOW_ADC_ON:
if (state->revision != 0x8090) {
reg_908 |= (1 << 1) | (1 << 0);
ret |= dib8000_write_word(state, 908, reg_908);
reg_908 &= ~(1 << 1);
} else {
reg = dib8000_read_word(state, 1925);
/* en_slowAdc = 1 & reset_sladc = 1 */
dib8000_write_word(state, 1925, reg |
(1<<4) | (1<<2));
/* read access to make it works... strange ... */
reg = dib8000_read_word(state, 1925);
msleep(20);
/* en_slowAdc = 1 & reset_sladc = 0 */
dib8000_write_word(state, 1925, reg & ~(1<<4));
reg = dib8000_read_word(state, 921) & ~((0x3 << 14)
| (0x3 << 12));
/* ref = Vin1 => Vbg ; sel = Vin0 or Vin3 ;
(Vin2 = Vcm) */
dib8000_write_word(state, 921, reg | (1 << 14)
| (3 << 12));
}
break;
case DIBX000_SLOW_ADC_OFF:
if (state->revision == 0x8090) {
reg = dib8000_read_word(state, 1925);
/* reset_sladc = 1 en_slowAdc = 0 */
dib8000_write_word(state, 1925,
(reg & ~(1<<2)) | (1<<4));
}
reg_908 |= (1 << 1) | (1 << 0);
break;
case DIBX000_ADC_ON:
reg_907 &= 0x0fff;
reg_908 &= 0x0003;
break;
case DIBX000_ADC_OFF: // leave the VBG voltage on
reg_907 = (1 << 13) | (1 << 12);
reg_908 = (1 << 6) | (1 << 5) | (1 << 4) | (1 << 3) | (1 << 1);
break;
case DIBX000_VBG_ENABLE:
reg_907 &= ~(1 << 15);
break;
case DIBX000_VBG_DISABLE:
reg_907 |= (1 << 15);
break;
default:
break;
}
ret |= dib8000_write_word(state, 907, reg_907);
ret |= dib8000_write_word(state, 908, reg_908);
return ret;
}
static int dib8000_set_bandwidth(struct dvb_frontend *fe, u32 bw)
{
struct dib8000_state *state = fe->demodulator_priv;
u32 timf;
if (bw == 0)
bw = 6000;
if (state->timf == 0) {
dprintk("using default timf\n");
timf = state->timf_default;
} else {
dprintk("using updated timf\n");
timf = state->timf;
}
dib8000_write_word(state, 29, (u16) ((timf >> 16) & 0xffff));
dib8000_write_word(state, 30, (u16) ((timf) & 0xffff));
return 0;
}
static int dib8000_sad_calib(struct dib8000_state *state)
{
u8 sad_sel = 3;
if (state->revision == 0x8090) {
dib8000_write_word(state, 922, (sad_sel << 2));
dib8000_write_word(state, 923, 2048);
dib8000_write_word(state, 922, (sad_sel << 2) | 0x1);
dib8000_write_word(state, 922, (sad_sel << 2));
} else {
/* internal */
dib8000_write_word(state, 923, (0 << 1) | (0 << 0));
dib8000_write_word(state, 924, 776);
/* do the calibration */
dib8000_write_word(state, 923, (1 << 0));
dib8000_write_word(state, 923, (0 << 0));
}
msleep(1);
return 0;
}
static int dib8000_set_wbd_ref(struct dvb_frontend *fe, u16 value)
{
struct dib8000_state *state = fe->demodulator_priv;
if (value > 4095)
value = 4095;
state->wbd_ref = value;
return dib8000_write_word(state, 106, value);
}
static void dib8000_reset_pll_common(struct dib8000_state *state, const struct dibx000_bandwidth_config *bw)
{
dprintk("ifreq: %d %x, inversion: %d\n", bw->ifreq, bw->ifreq, bw->ifreq >> 25);
if (state->revision != 0x8090) {
dib8000_write_word(state, 23,
(u16) (((bw->internal * 1000) >> 16) & 0xffff));
dib8000_write_word(state, 24,
(u16) ((bw->internal * 1000) & 0xffff));
} else {
dib8000_write_word(state, 23, (u16) (((bw->internal / 2 * 1000) >> 16) & 0xffff));
dib8000_write_word(state, 24,
(u16) ((bw->internal / 2 * 1000) & 0xffff));
}
dib8000_write_word(state, 27, (u16) ((bw->ifreq >> 16) & 0x01ff));
dib8000_write_word(state, 28, (u16) (bw->ifreq & 0xffff));
dib8000_write_word(state, 26, (u16) ((bw->ifreq >> 25) & 0x0003));
if (state->revision != 0x8090)
dib8000_write_word(state, 922, bw->sad_cfg);
}
static void dib8000_reset_pll(struct dib8000_state *state)
{
const struct dibx000_bandwidth_config *pll = state->cfg.pll;
u16 clk_cfg1, reg;
if (state->revision != 0x8090) {
dib8000_write_word(state, 901,
(pll->pll_prediv << 8) | (pll->pll_ratio << 0));
clk_cfg1 = (1 << 10) | (0 << 9) | (pll->IO_CLK_en_core << 8) |
(pll->bypclk_div << 5) | (pll->enable_refdiv << 4) |
(1 << 3) | (pll->pll_range << 1) |
(pll->pll_reset << 0);
dib8000_write_word(state, 902, clk_cfg1);
clk_cfg1 = (clk_cfg1 & 0xfff7) | (pll->pll_bypass << 3);
dib8000_write_word(state, 902, clk_cfg1);
dprintk("clk_cfg1: 0x%04x\n", clk_cfg1);
/* smpl_cfg: P_refclksel=2, P_ensmplsel=1 nodivsmpl=1 */
if (state->cfg.pll->ADClkSrc == 0)
dib8000_write_word(state, 904,
(0 << 15) | (0 << 12) | (0 << 10) |
(pll->modulo << 8) |
(pll->ADClkSrc << 7) | (0 << 1));
else if (state->cfg.refclksel != 0)
dib8000_write_word(state, 904, (0 << 15) | (1 << 12) |
((state->cfg.refclksel & 0x3) << 10) |
(pll->modulo << 8) |
(pll->ADClkSrc << 7) | (0 << 1));
else
dib8000_write_word(state, 904, (0 << 15) | (1 << 12) |
(3 << 10) | (pll->modulo << 8) |
(pll->ADClkSrc << 7) | (0 << 1));
} else {
dib8000_write_word(state, 1856, (!pll->pll_reset<<13) |
(pll->pll_range<<12) | (pll->pll_ratio<<6) |
(pll->pll_prediv));
reg = dib8000_read_word(state, 1857);
dib8000_write_word(state, 1857, reg|(!pll->pll_bypass<<15));
reg = dib8000_read_word(state, 1858); /* Force clk out pll /2 */
dib8000_write_word(state, 1858, reg | 1);
dib8000_write_word(state, 904, (pll->modulo << 8));
}
dib8000_reset_pll_common(state, pll);
}
static int dib8000_update_pll(struct dvb_frontend *fe,
struct dibx000_bandwidth_config *pll, u32 bw, u8 ratio)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 reg_1857, reg_1856 = dib8000_read_word(state, 1856);
u8 loopdiv, prediv, oldprediv = state->cfg.pll->pll_prediv ;
u32 internal, xtal;
/* get back old values */
prediv = reg_1856 & 0x3f;
loopdiv = (reg_1856 >> 6) & 0x3f;
if ((pll == NULL) || (pll->pll_prediv == prediv &&
pll->pll_ratio == loopdiv))
return -EINVAL;
dprintk("Updating pll (prediv: old = %d new = %d ; loopdiv : old = %d new = %d)\n", prediv, pll->pll_prediv, loopdiv, pll->pll_ratio);
if (state->revision == 0x8090) {
reg_1856 &= 0xf000;
reg_1857 = dib8000_read_word(state, 1857);
/* disable PLL */
dib8000_write_word(state, 1857, reg_1857 & ~(1 << 15));
dib8000_write_word(state, 1856, reg_1856 |
((pll->pll_ratio & 0x3f) << 6) |
(pll->pll_prediv & 0x3f));
/* write new system clk into P_sec_len */
internal = dib8000_read32(state, 23) / 1000;
dprintk("Old Internal = %d\n", internal);
xtal = 2 * (internal / loopdiv) * prediv;
internal = 1000 * (xtal/pll->pll_prediv) * pll->pll_ratio;
dprintk("Xtal = %d , New Fmem = %d New Fdemod = %d, New Fsampling = %d\n", xtal, internal/1000, internal/2000, internal/8000);
dprintk("New Internal = %d\n", internal);
dib8000_write_word(state, 23,
(u16) (((internal / 2) >> 16) & 0xffff));
dib8000_write_word(state, 24, (u16) ((internal / 2) & 0xffff));
/* enable PLL */
dib8000_write_word(state, 1857, reg_1857 | (1 << 15));
while (((dib8000_read_word(state, 1856)>>15)&0x1) != 1)
dprintk("Waiting for PLL to lock\n");
/* verify */
reg_1856 = dib8000_read_word(state, 1856);
dprintk("PLL Updated with prediv = %d and loopdiv = %d\n",
reg_1856&0x3f, (reg_1856>>6)&0x3f);
} else {
if (bw != state->current_demod_bw) {
/** Bandwidth change => force PLL update **/
dprintk("PLL: Bandwidth Change %d MHz -> %d MHz (prediv: %d->%d)\n", state->current_demod_bw / 1000, bw / 1000, oldprediv, state->cfg.pll->pll_prediv);
if (state->cfg.pll->pll_prediv != oldprediv) {
/** Full PLL change only if prediv is changed **/
/** full update => bypass and reconfigure **/
dprintk("PLL: New Setting for %d MHz Bandwidth (prediv: %d, ratio: %d)\n", bw/1000, state->cfg.pll->pll_prediv, state->cfg.pll->pll_ratio);
dib8000_write_word(state, 902, dib8000_read_word(state, 902) | (1<<3)); /* bypass PLL */
dib8000_reset_pll(state);
dib8000_write_word(state, 898, 0x0004); /* sad */
} else
ratio = state->cfg.pll->pll_ratio;
state->current_demod_bw = bw;
}
if (ratio != 0) {
/** ratio update => only change ratio **/
dprintk("PLL: Update ratio (prediv: %d, ratio: %d)\n", state->cfg.pll->pll_prediv, ratio);
dib8000_write_word(state, 901, (state->cfg.pll->pll_prediv << 8) | (ratio << 0)); /* only the PLL ratio is updated. */
}
}
return 0;
}
static int dib8000_reset_gpio(struct dib8000_state *st)
{
/* reset the GPIOs */
dib8000_write_word(st, 1029, st->cfg.gpio_dir);
dib8000_write_word(st, 1030, st->cfg.gpio_val);
/* TODO 782 is P_gpio_od */
dib8000_write_word(st, 1032, st->cfg.gpio_pwm_pos);
dib8000_write_word(st, 1037, st->cfg.pwm_freq_div);
return 0;
}
static int dib8000_cfg_gpio(struct dib8000_state *st, u8 num, u8 dir, u8 val)
{
st->cfg.gpio_dir = dib8000_read_word(st, 1029);
st->cfg.gpio_dir &= ~(1 << num); /* reset the direction bit */
st->cfg.gpio_dir |= (dir & 0x1) << num; /* set the new direction */
dib8000_write_word(st, 1029, st->cfg.gpio_dir);
st->cfg.gpio_val = dib8000_read_word(st, 1030);
st->cfg.gpio_val &= ~(1 << num); /* reset the direction bit */
st->cfg.gpio_val |= (val & 0x01) << num; /* set the new value */
dib8000_write_word(st, 1030, st->cfg.gpio_val);
dprintk("gpio dir: %x: gpio val: %x\n", st->cfg.gpio_dir, st->cfg.gpio_val);
return 0;
}
static int dib8000_set_gpio(struct dvb_frontend *fe, u8 num, u8 dir, u8 val)
{
struct dib8000_state *state = fe->demodulator_priv;
return dib8000_cfg_gpio(state, num, dir, val);
}
static const u16 dib8000_defaults[] = {
/* auto search configuration - lock0 by default waiting
* for cpil_lock; lock1 cpil_lock; lock2 tmcc_sync_lock */
3, 7,
0x0004,
0x0400,
0x0814,
12, 11,
0x001b,
0x7740,
0x005b,
0x8d80,
0x01c9,
0xc380,
0x0000,
0x0080,
0x0000,
0x0090,
0x0001,
0xd4c0,
/*1, 32,
0x6680 // P_corm_thres Lock algorithms configuration */
11, 80, /* set ADC level to -16 */
(1 << 13) - 825 - 117,
(1 << 13) - 837 - 117,
(1 << 13) - 811 - 117,
(1 << 13) - 766 - 117,
(1 << 13) - 737 - 117,
(1 << 13) - 693 - 117,
(1 << 13) - 648 - 117,
(1 << 13) - 619 - 117,
(1 << 13) - 575 - 117,
(1 << 13) - 531 - 117,
(1 << 13) - 501 - 117,
4, 108,
0,
0,
0,
0,
1, 175,
0x0410,
1, 179,
8192, // P_fft_nb_to_cut
6, 181,
0x2800, // P_coff_corthres_ ( 2k 4k 8k ) 0x2800
0x2800,
0x2800,
0x2800, // P_coff_cpilthres_ ( 2k 4k 8k ) 0x2800
0x2800,
0x2800,
2, 193,
0x0666, // P_pha3_thres
0x0000, // P_cti_use_cpe, P_cti_use_prog
2, 205,
0x200f, // P_cspu_regul, P_cspu_win_cut
0x000f, // P_des_shift_work
5, 215,
0x023d, // P_adp_regul_cnt
0x00a4, // P_adp_noise_cnt
0x00a4, // P_adp_regul_ext
0x7ff0, // P_adp_noise_ext
0x3ccc, // P_adp_fil
1, 230,
0x0000, // P_2d_byp_ti_num
1, 263,
0x800, //P_equal_thres_wgn
1, 268,
(2 << 9) | 39, // P_equal_ctrl_synchro, P_equal_speedmode
1, 270,
0x0001, // P_div_lock0_wait
1, 285,
0x0020, //p_fec_
1, 299,
0x0062, /* P_smo_mode, P_smo_rs_discard, P_smo_fifo_flush, P_smo_pid_parse, P_smo_error_discard */
1, 338,
(1 << 12) | // P_ctrl_corm_thres4pre_freq_inh=1
(1 << 10) |
(0 << 9) | /* P_ctrl_pre_freq_inh=0 */
(3 << 5) | /* P_ctrl_pre_freq_step=3 */
(1 << 0), /* P_pre_freq_win_len=1 */
0,
};
static u16 dib8000_identify(struct i2c_device *client)
{
u16 value;
//because of glitches sometimes
value = dib8000_i2c_read16(client, 896);
if ((value = dib8000_i2c_read16(client, 896)) != 0x01b3) {
dprintk("wrong Vendor ID (read=0x%x)\n", value);
return 0;
}
value = dib8000_i2c_read16(client, 897);
if (value != 0x8000 && value != 0x8001 &&
value != 0x8002 && value != 0x8090) {
dprintk("wrong Device ID (%x)\n", value);
return 0;
}
switch (value) {
case 0x8000:
dprintk("found DiB8000A\n");
break;
case 0x8001:
dprintk("found DiB8000B\n");
break;
case 0x8002:
dprintk("found DiB8000C\n");
break;
case 0x8090:
dprintk("found DiB8096P\n");
break;
}
return value;
}
static int dib8000_read_unc_blocks(struct dvb_frontend *fe, u32 *unc);
static void dib8000_reset_stats(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
u32 ucb;
memset(&c->strength, 0, sizeof(c->strength));
memset(&c->cnr, 0, sizeof(c->cnr));
memset(&c->post_bit_error, 0, sizeof(c->post_bit_error));
memset(&c->post_bit_count, 0, sizeof(c->post_bit_count));
memset(&c->block_error, 0, sizeof(c->block_error));
c->strength.len = 1;
c->cnr.len = 1;
c->block_error.len = 1;
c->block_count.len = 1;
c->post_bit_error.len = 1;
c->post_bit_count.len = 1;
c->strength.stat[0].scale = FE_SCALE_DECIBEL;
c->strength.stat[0].uvalue = 0;
c->cnr.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->block_error.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->block_count.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->post_bit_error.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->post_bit_count.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
dib8000_read_unc_blocks(fe, &ucb);
state->init_ucb = -ucb;
state->ber_jiffies_stats = 0;
state->per_jiffies_stats = 0;
memset(&state->ber_jiffies_stats_layer, 0,
sizeof(state->ber_jiffies_stats_layer));
}
static int dib8000_reset(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
if ((state->revision = dib8000_identify(&state->i2c)) == 0)
return -EINVAL;
/* sram lead in, rdy */
if (state->revision != 0x8090)
dib8000_write_word(state, 1287, 0x0003);
if (state->revision == 0x8000)
dprintk("error : dib8000 MA not supported\n");
dibx000_reset_i2c_master(&state->i2c_master);
dib8000_set_power_mode(state, DIB8000_POWER_ALL);
/* always leave the VBG voltage on - it consumes almost nothing but takes a long time to start */
dib8000_set_adc_state(state, DIBX000_ADC_OFF);
/* restart all parts */
dib8000_write_word(state, 770, 0xffff);
dib8000_write_word(state, 771, 0xffff);
dib8000_write_word(state, 772, 0xfffc);
dib8000_write_word(state, 898, 0x000c); /* restart sad */
if (state->revision == 0x8090)
dib8000_write_word(state, 1280, 0x0045);
else
dib8000_write_word(state, 1280, 0x004d);
dib8000_write_word(state, 1281, 0x000c);
dib8000_write_word(state, 770, 0x0000);
dib8000_write_word(state, 771, 0x0000);
dib8000_write_word(state, 772, 0x0000);
dib8000_write_word(state, 898, 0x0004); // sad
dib8000_write_word(state, 1280, 0x0000);
dib8000_write_word(state, 1281, 0x0000);
/* drives */
if (state->revision != 0x8090) {
if (state->cfg.drives)
dib8000_write_word(state, 906, state->cfg.drives);
else {
dprintk("using standard PAD-drive-settings, please adjust settings in config-struct to be optimal.\n");
/* min drive SDRAM - not optimal - adjust */
dib8000_write_word(state, 906, 0x2d98);
}
}
dib8000_reset_pll(state);
if (state->revision != 0x8090)
dib8000_write_word(state, 898, 0x0004);
if (dib8000_reset_gpio(state) != 0)
dprintk("GPIO reset was not successful.\n");
if ((state->revision != 0x8090) &&
(dib8000_set_output_mode(fe, OUTMODE_HIGH_Z) != 0))
dprintk("OUTPUT_MODE could not be reset.\n");
state->current_agc = NULL;
// P_iqc_alpha_pha, P_iqc_alpha_amp, P_iqc_dcc_alpha, ...
/* P_iqc_ca2 = 0; P_iqc_impnc_on = 0; P_iqc_mode = 0; */
if (state->cfg.pll->ifreq == 0)
dib8000_write_word(state, 40, 0x0755); /* P_iqc_corr_inh = 0 enable IQcorr block */
else
dib8000_write_word(state, 40, 0x1f55); /* P_iqc_corr_inh = 1 disable IQcorr block */
{
u16 l = 0, r;
const u16 *n;
n = dib8000_defaults;
l = *n++;
while (l) {
r = *n++;
do {
dib8000_write_word(state, r, *n++);
r++;
} while (--l);
l = *n++;
}
}
state->isdbt_cfg_loaded = 0;
//div_cfg override for special configs
if ((state->revision != 8090) && (state->cfg.div_cfg != 0))
dib8000_write_word(state, 903, state->cfg.div_cfg);
/* unforce divstr regardless whether i2c enumeration was done or not */
dib8000_write_word(state, 1285, dib8000_read_word(state, 1285) & ~(1 << 1));
dib8000_set_bandwidth(fe, 6000);
dib8000_set_adc_state(state, DIBX000_SLOW_ADC_ON);
dib8000_sad_calib(state);
if (state->revision != 0x8090)
dib8000_set_adc_state(state, DIBX000_SLOW_ADC_OFF);
/* ber_rs_len = 3 */
dib8000_write_word(state, 285, (dib8000_read_word(state, 285) & ~0x60) | (3 << 5));
dib8000_set_power_mode(state, DIB8000_POWER_INTERFACE_ONLY);
dib8000_reset_stats(fe);
return 0;
}
static void dib8000_restart_agc(struct dib8000_state *state)
{
// P_restart_iqc & P_restart_agc
dib8000_write_word(state, 770, 0x0a00);
dib8000_write_word(state, 770, 0x0000);
}
static int dib8000_update_lna(struct dib8000_state *state)
{
u16 dyn_gain;
if (state->cfg.update_lna) {
// read dyn_gain here (because it is demod-dependent and not tuner)
dyn_gain = dib8000_read_word(state, 390);
if (state->cfg.update_lna(state->fe[0], dyn_gain)) {
dib8000_restart_agc(state);
return 1;
}
}
return 0;
}
static int dib8000_set_agc_config(struct dib8000_state *state, u8 band)
{
struct dibx000_agc_config *agc = NULL;
int i;
u16 reg;
if (state->current_band == band && state->current_agc != NULL)
return 0;
state->current_band = band;
for (i = 0; i < state->cfg.agc_config_count; i++)
if (state->cfg.agc[i].band_caps & band) {
agc = &state->cfg.agc[i];
break;
}
if (agc == NULL) {
dprintk("no valid AGC configuration found for band 0x%02x\n", band);
return -EINVAL;
}
state->current_agc = agc;
/* AGC */
dib8000_write_word(state, 76, agc->setup);
dib8000_write_word(state, 77, agc->inv_gain);
dib8000_write_word(state, 78, agc->time_stabiliz);
dib8000_write_word(state, 101, (agc->alpha_level << 12) | agc->thlock);
// Demod AGC loop configuration
dib8000_write_word(state, 102, (agc->alpha_mant << 5) | agc->alpha_exp);
dib8000_write_word(state, 103, (agc->beta_mant << 6) | agc->beta_exp);
dprintk("WBD: ref: %d, sel: %d, active: %d, alpha: %d\n",
state->wbd_ref != 0 ? state->wbd_ref : agc->wbd_ref, agc->wbd_sel, !agc->perform_agc_softsplit, agc->wbd_sel);
/* AGC continued */
if (state->wbd_ref != 0)
dib8000_write_word(state, 106, state->wbd_ref);
else // use default
dib8000_write_word(state, 106, agc->wbd_ref);
if (state->revision == 0x8090) {
reg = dib8000_read_word(state, 922) & (0x3 << 2);
dib8000_write_word(state, 922, reg | (agc->wbd_sel << 2));
}
dib8000_write_word(state, 107, (agc->wbd_alpha << 9) | (agc->perform_agc_softsplit << 8));
dib8000_write_word(state, 108, agc->agc1_max);
dib8000_write_word(state, 109, agc->agc1_min);
dib8000_write_word(state, 110, agc->agc2_max);
dib8000_write_word(state, 111, agc->agc2_min);
dib8000_write_word(state, 112, (agc->agc1_pt1 << 8) | agc->agc1_pt2);
dib8000_write_word(state, 113, (agc->agc1_slope1 << 8) | agc->agc1_slope2);
dib8000_write_word(state, 114, (agc->agc2_pt1 << 8) | agc->agc2_pt2);
dib8000_write_word(state, 115, (agc->agc2_slope1 << 8) | agc->agc2_slope2);
dib8000_write_word(state, 75, agc->agc1_pt3);
if (state->revision != 0x8090)
dib8000_write_word(state, 923,
(dib8000_read_word(state, 923) & 0xffe3) |
(agc->wbd_inv << 4) | (agc->wbd_sel << 2));
return 0;
}
static void dib8000_pwm_agc_reset(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
dib8000_set_adc_state(state, DIBX000_ADC_ON);
dib8000_set_agc_config(state, (unsigned char)(BAND_OF_FREQUENCY(fe->dtv_property_cache.frequency / 1000)));
}
static int dib8000_agc_soft_split(struct dib8000_state *state)
{
u16 agc, split_offset;
if (!state->current_agc || !state->current_agc->perform_agc_softsplit || state->current_agc->split.max == 0)
return 0;
// n_agc_global
agc = dib8000_read_word(state, 390);
if (agc > state->current_agc->split.min_thres)
split_offset = state->current_agc->split.min;
else if (agc < state->current_agc->split.max_thres)
split_offset = state->current_agc->split.max;
else
split_offset = state->current_agc->split.max *
(agc - state->current_agc->split.min_thres) /
(state->current_agc->split.max_thres - state->current_agc->split.min_thres);
dprintk("AGC split_offset: %d\n", split_offset);
// P_agc_force_split and P_agc_split_offset
dib8000_write_word(state, 107, (dib8000_read_word(state, 107) & 0xff00) | split_offset);
return 5000;
}
static int dib8000_agc_startup(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
enum frontend_tune_state *tune_state = &state->tune_state;
int ret = 0;
u16 reg;
u32 upd_demod_gain_period = 0x8000;
switch (*tune_state) {
case CT_AGC_START:
// set power-up level: interf+analog+AGC
if (state->revision != 0x8090)
dib8000_set_adc_state(state, DIBX000_ADC_ON);
else {
dib8000_set_power_mode(state, DIB8000_POWER_ALL);
reg = dib8000_read_word(state, 1947)&0xff00;
dib8000_write_word(state, 1946,
upd_demod_gain_period & 0xFFFF);
/* bit 14 = enDemodGain */
dib8000_write_word(state, 1947, reg | (1<<14) |
((upd_demod_gain_period >> 16) & 0xFF));
/* enable adc i & q */
reg = dib8000_read_word(state, 1920);
dib8000_write_word(state, 1920, (reg | 0x3) &
(~(1 << 7)));
}
if (dib8000_set_agc_config(state, (unsigned char)(BAND_OF_FREQUENCY(fe->dtv_property_cache.frequency / 1000))) != 0) {
*tune_state = CT_AGC_STOP;
state->status = FE_STATUS_TUNE_FAILED;
break;
}
ret = 70;
*tune_state = CT_AGC_STEP_0;
break;
case CT_AGC_STEP_0:
//AGC initialization
if (state->cfg.agc_control)
state->cfg.agc_control(fe, 1);
dib8000_restart_agc(state);
// wait AGC rough lock time
ret = 50;
*tune_state = CT_AGC_STEP_1;
break;
case CT_AGC_STEP_1:
// wait AGC accurate lock time
ret = 70;
if (dib8000_update_lna(state))
// wait only AGC rough lock time
ret = 50;
else
*tune_state = CT_AGC_STEP_2;
break;
case CT_AGC_STEP_2:
dib8000_agc_soft_split(state);
if (state->cfg.agc_control)
state->cfg.agc_control(fe, 0);
*tune_state = CT_AGC_STOP;
break;
default:
ret = dib8000_agc_soft_split(state);
break;
}
return ret;
}
static void dib8096p_host_bus_drive(struct dib8000_state *state, u8 drive)
{
u16 reg;
drive &= 0x7;
/* drive host bus 2, 3, 4 */
reg = dib8000_read_word(state, 1798) &
~(0x7 | (0x7 << 6) | (0x7 << 12));
reg |= (drive<<12) | (drive<<6) | drive;
dib8000_write_word(state, 1798, reg);
/* drive host bus 5,6 */
reg = dib8000_read_word(state, 1799) & ~((0x7 << 2) | (0x7 << 8));
reg |= (drive<<8) | (drive<<2);
dib8000_write_word(state, 1799, reg);
/* drive host bus 7, 8, 9 */
reg = dib8000_read_word(state, 1800) &
~(0x7 | (0x7 << 6) | (0x7 << 12));
reg |= (drive<<12) | (drive<<6) | drive;
dib8000_write_word(state, 1800, reg);
/* drive host bus 10, 11 */
reg = dib8000_read_word(state, 1801) & ~((0x7 << 2) | (0x7 << 8));
reg |= (drive<<8) | (drive<<2);
dib8000_write_word(state, 1801, reg);
/* drive host bus 12, 13, 14 */
reg = dib8000_read_word(state, 1802) &
~(0x7 | (0x7 << 6) | (0x7 << 12));
reg |= (drive<<12) | (drive<<6) | drive;
dib8000_write_word(state, 1802, reg);
}
static u32 dib8096p_calcSyncFreq(u32 P_Kin, u32 P_Kout,
u32 insertExtSynchro, u32 syncSize)
{
u32 quantif = 3;
u32 nom = (insertExtSynchro * P_Kin+syncSize);
u32 denom = P_Kout;
u32 syncFreq = ((nom << quantif) / denom);
if ((syncFreq & ((1 << quantif) - 1)) != 0)
syncFreq = (syncFreq >> quantif) + 1;
else
syncFreq = (syncFreq >> quantif);
if (syncFreq != 0)
syncFreq = syncFreq - 1;
return syncFreq;
}
static void dib8096p_cfg_DibTx(struct dib8000_state *state, u32 P_Kin,
u32 P_Kout, u32 insertExtSynchro, u32 synchroMode,
u32 syncWord, u32 syncSize)
{
dprintk("Configure DibStream Tx\n");
dib8000_write_word(state, 1615, 1);
dib8000_write_word(state, 1603, P_Kin);
dib8000_write_word(state, 1605, P_Kout);
dib8000_write_word(state, 1606, insertExtSynchro);
dib8000_write_word(state, 1608, synchroMode);
dib8000_write_word(state, 1609, (syncWord >> 16) & 0xffff);
dib8000_write_word(state, 1610, syncWord & 0xffff);
dib8000_write_word(state, 1612, syncSize);
dib8000_write_word(state, 1615, 0);
}
static void dib8096p_cfg_DibRx(struct dib8000_state *state, u32 P_Kin,
u32 P_Kout, u32 synchroMode, u32 insertExtSynchro,
u32 syncWord, u32 syncSize, u32 dataOutRate)
{
u32 syncFreq;
dprintk("Configure DibStream Rx synchroMode = %d\n", synchroMode);
if ((P_Kin != 0) && (P_Kout != 0)) {
syncFreq = dib8096p_calcSyncFreq(P_Kin, P_Kout,
insertExtSynchro, syncSize);
dib8000_write_word(state, 1542, syncFreq);
}
dib8000_write_word(state, 1554, 1);
dib8000_write_word(state, 1536, P_Kin);
dib8000_write_word(state, 1537, P_Kout);
dib8000_write_word(state, 1539, synchroMode);
dib8000_write_word(state, 1540, (syncWord >> 16) & 0xffff);
dib8000_write_word(state, 1541, syncWord & 0xffff);
dib8000_write_word(state, 1543, syncSize);
dib8000_write_word(state, 1544, dataOutRate);
dib8000_write_word(state, 1554, 0);
}
static void dib8096p_enMpegMux(struct dib8000_state *state, int onoff)
{
u16 reg_1287;
reg_1287 = dib8000_read_word(state, 1287);
switch (onoff) {
case 1:
reg_1287 &= ~(1 << 8);
break;
case 0:
reg_1287 |= (1 << 8);
break;
}
dib8000_write_word(state, 1287, reg_1287);
}
static void dib8096p_configMpegMux(struct dib8000_state *state,
u16 pulseWidth, u16 enSerialMode, u16 enSerialClkDiv2)
{
u16 reg_1287;
dprintk("Enable Mpeg mux\n");
dib8096p_enMpegMux(state, 0);
/* If the input mode is MPEG do not divide the serial clock */
if ((enSerialMode == 1) && (state->input_mode_mpeg == 1))
enSerialClkDiv2 = 0;
reg_1287 = ((pulseWidth & 0x1f) << 3) |
((enSerialMode & 0x1) << 2) | (enSerialClkDiv2 & 0x1);
dib8000_write_word(state, 1287, reg_1287);
dib8096p_enMpegMux(state, 1);
}
static void dib8096p_setDibTxMux(struct dib8000_state *state, int mode)
{
u16 reg_1288 = dib8000_read_word(state, 1288) & ~(0x7 << 7);
switch (mode) {
case MPEG_ON_DIBTX:
dprintk("SET MPEG ON DIBSTREAM TX\n");
dib8096p_cfg_DibTx(state, 8, 5, 0, 0, 0, 0);
reg_1288 |= (1 << 9); break;
case DIV_ON_DIBTX:
dprintk("SET DIV_OUT ON DIBSTREAM TX\n");
dib8096p_cfg_DibTx(state, 5, 5, 0, 0, 0, 0);
reg_1288 |= (1 << 8); break;
case ADC_ON_DIBTX:
dprintk("SET ADC_OUT ON DIBSTREAM TX\n");
dib8096p_cfg_DibTx(state, 20, 5, 10, 0, 0, 0);
reg_1288 |= (1 << 7); break;
default:
break;
}
dib8000_write_word(state, 1288, reg_1288);
}
static void dib8096p_setHostBusMux(struct dib8000_state *state, int mode)
{
u16 reg_1288 = dib8000_read_word(state, 1288) & ~(0x7 << 4);
switch (mode) {
case DEMOUT_ON_HOSTBUS:
dprintk("SET DEM OUT OLD INTERF ON HOST BUS\n");
dib8096p_enMpegMux(state, 0);
reg_1288 |= (1 << 6);
break;
case DIBTX_ON_HOSTBUS:
dprintk("SET DIBSTREAM TX ON HOST BUS\n");
dib8096p_enMpegMux(state, 0);
reg_1288 |= (1 << 5);
break;
case MPEG_ON_HOSTBUS:
dprintk("SET MPEG MUX ON HOST BUS\n");
reg_1288 |= (1 << 4);
break;
default:
break;
}
dib8000_write_word(state, 1288, reg_1288);
}
static int dib8096p_set_diversity_in(struct dvb_frontend *fe, int onoff)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 reg_1287;
switch (onoff) {
case 0: /* only use the internal way - not the diversity input */
dprintk("%s mode OFF : by default Enable Mpeg INPUT\n",
__func__);
/* outputRate = 8 */
dib8096p_cfg_DibRx(state, 8, 5, 0, 0, 0, 8, 0);
/* Do not divide the serial clock of MPEG MUX in
SERIAL MODE in case input mode MPEG is used */
reg_1287 = dib8000_read_word(state, 1287);
/* enSerialClkDiv2 == 1 ? */
if ((reg_1287 & 0x1) == 1) {
/* force enSerialClkDiv2 = 0 */
reg_1287 &= ~0x1;
dib8000_write_word(state, 1287, reg_1287);
}
state->input_mode_mpeg = 1;
break;
case 1: /* both ways */
case 2: /* only the diversity input */
dprintk("%s ON : Enable diversity INPUT\n", __func__);
dib8096p_cfg_DibRx(state, 5, 5, 0, 0, 0, 0, 0);
state->input_mode_mpeg = 0;
break;
}
dib8000_set_diversity_in(state->fe[0], onoff);
return 0;
}
static int dib8096p_set_output_mode(struct dvb_frontend *fe, int mode)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 outreg, smo_mode, fifo_threshold;
u8 prefer_mpeg_mux_use = 1;
int ret = 0;
state->output_mode = mode;
dib8096p_host_bus_drive(state, 1);
fifo_threshold = 1792;
smo_mode = (dib8000_read_word(state, 299) & 0x0050) | (1 << 1);
outreg = dib8000_read_word(state, 1286) &
~((1 << 10) | (0x7 << 6) | (1 << 1));
switch (mode) {
case OUTMODE_HIGH_Z:
outreg = 0;
break;
case OUTMODE_MPEG2_SERIAL:
if (prefer_mpeg_mux_use) {
dprintk("dib8096P setting output mode TS_SERIAL using Mpeg Mux\n");
dib8096p_configMpegMux(state, 3, 1, 1);
dib8096p_setHostBusMux(state, MPEG_ON_HOSTBUS);
} else {/* Use Smooth block */
dprintk("dib8096P setting output mode TS_SERIAL using Smooth bloc\n");
dib8096p_setHostBusMux(state,
DEMOUT_ON_HOSTBUS);
outreg |= (2 << 6) | (0 << 1);
}
break;
case OUTMODE_MPEG2_PAR_GATED_CLK:
if (prefer_mpeg_mux_use) {
dprintk("dib8096P setting output mode TS_PARALLEL_GATED using Mpeg Mux\n");
dib8096p_configMpegMux(state, 2, 0, 0);
dib8096p_setHostBusMux(state, MPEG_ON_HOSTBUS);
} else { /* Use Smooth block */
dprintk("dib8096P setting output mode TS_PARALLEL_GATED using Smooth block\n");
dib8096p_setHostBusMux(state,
DEMOUT_ON_HOSTBUS);
outreg |= (0 << 6);
}
break;
case OUTMODE_MPEG2_PAR_CONT_CLK: /* Using Smooth block only */
dprintk("dib8096P setting output mode TS_PARALLEL_CONT using Smooth block\n");
dib8096p_setHostBusMux(state, DEMOUT_ON_HOSTBUS);
outreg |= (1 << 6);
break;
case OUTMODE_MPEG2_FIFO:
/* Using Smooth block because not supported
by new Mpeg Mux bloc */
dprintk("dib8096P setting output mode TS_FIFO using Smooth block\n");
dib8096p_setHostBusMux(state, DEMOUT_ON_HOSTBUS);
outreg |= (5 << 6);
smo_mode |= (3 << 1);
fifo_threshold = 512;
break;
case OUTMODE_DIVERSITY:
dprintk("dib8096P setting output mode MODE_DIVERSITY\n");
dib8096p_setDibTxMux(state, DIV_ON_DIBTX);
dib8096p_setHostBusMux(state, DIBTX_ON_HOSTBUS);
break;
case OUTMODE_ANALOG_ADC:
dprintk("dib8096P setting output mode MODE_ANALOG_ADC\n");
dib8096p_setDibTxMux(state, ADC_ON_DIBTX);
dib8096p_setHostBusMux(state, DIBTX_ON_HOSTBUS);
break;
}
if (mode != OUTMODE_HIGH_Z)
outreg |= (1<<10);
dprintk("output_mpeg2_in_188_bytes = %d\n",
state->cfg.output_mpeg2_in_188_bytes);
if (state->cfg.output_mpeg2_in_188_bytes)
smo_mode |= (1 << 5);
ret |= dib8000_write_word(state, 299, smo_mode);
/* synchronous fread */
ret |= dib8000_write_word(state, 299 + 1, fifo_threshold);
ret |= dib8000_write_word(state, 1286, outreg);
return ret;
}
static int map_addr_to_serpar_number(struct i2c_msg *msg)
{
if (msg->buf[0] <= 15)
msg->buf[0] -= 1;
else if (msg->buf[0] == 17)
msg->buf[0] = 15;
else if (msg->buf[0] == 16)
msg->buf[0] = 17;
else if (msg->buf[0] == 19)
msg->buf[0] = 16;
else if (msg->buf[0] >= 21 && msg->buf[0] <= 25)
msg->buf[0] -= 3;
else if (msg->buf[0] == 28)
msg->buf[0] = 23;
else if (msg->buf[0] == 99)
msg->buf[0] = 99;
else
return -EINVAL;
return 0;
}
static int dib8096p_tuner_write_serpar(struct i2c_adapter *i2c_adap,
struct i2c_msg msg[], int num)
{
struct dib8000_state *state = i2c_get_adapdata(i2c_adap);
u8 n_overflow = 1;
u16 i = 1000;
u16 serpar_num = msg[0].buf[0];
while (n_overflow == 1 && i) {
n_overflow = (dib8000_read_word(state, 1984) >> 1) & 0x1;
i--;
if (i == 0)
dprintk("Tuner ITF: write busy (overflow)\n");
}
dib8000_write_word(state, 1985, (1 << 6) | (serpar_num & 0x3f));
dib8000_write_word(state, 1986, (msg[0].buf[1] << 8) | msg[0].buf[2]);
return num;
}
static int dib8096p_tuner_read_serpar(struct i2c_adapter *i2c_adap,
struct i2c_msg msg[], int num)
{
struct dib8000_state *state = i2c_get_adapdata(i2c_adap);
u8 n_overflow = 1, n_empty = 1;
u16 i = 1000;
u16 serpar_num = msg[0].buf[0];
u16 read_word;
while (n_overflow == 1 && i) {
n_overflow = (dib8000_read_word(state, 1984) >> 1) & 0x1;
i--;
if (i == 0)
dprintk("TunerITF: read busy (overflow)\n");
}
dib8000_write_word(state, 1985, (0<<6) | (serpar_num&0x3f));
i = 1000;
while (n_empty == 1 && i) {
n_empty = dib8000_read_word(state, 1984)&0x1;
i--;
if (i == 0)
dprintk("TunerITF: read busy (empty)\n");
}
read_word = dib8000_read_word(state, 1987);
msg[1].buf[0] = (read_word >> 8) & 0xff;
msg[1].buf[1] = (read_word) & 0xff;
return num;
}
static int dib8096p_tuner_rw_serpar(struct i2c_adapter *i2c_adap,
struct i2c_msg msg[], int num)
{
if (map_addr_to_serpar_number(&msg[0]) == 0) {
if (num == 1) /* write */
return dib8096p_tuner_write_serpar(i2c_adap, msg, 1);
else /* read */
return dib8096p_tuner_read_serpar(i2c_adap, msg, 2);
}
return num;
}
static int dib8096p_rw_on_apb(struct i2c_adapter *i2c_adap,
struct i2c_msg msg[], int num, u16 apb_address)
{
struct dib8000_state *state = i2c_get_adapdata(i2c_adap);
u16 word;
if (num == 1) { /* write */
dib8000_write_word(state, apb_address,
((msg[0].buf[1] << 8) | (msg[0].buf[2])));
} else {
word = dib8000_read_word(state, apb_address);
msg[1].buf[0] = (word >> 8) & 0xff;
msg[1].buf[1] = (word) & 0xff;
}
return num;
}
static int dib8096p_tuner_xfer(struct i2c_adapter *i2c_adap,
struct i2c_msg msg[], int num)
{
struct dib8000_state *state = i2c_get_adapdata(i2c_adap);
u16 apb_address = 0, word;
int i = 0;
switch (msg[0].buf[0]) {
case 0x12:
apb_address = 1920;
break;
case 0x14:
apb_address = 1921;
break;
case 0x24:
apb_address = 1922;
break;
case 0x1a:
apb_address = 1923;
break;
case 0x22:
apb_address = 1924;
break;
case 0x33:
apb_address = 1926;
break;
case 0x34:
apb_address = 1927;
break;
case 0x35:
apb_address = 1928;
break;
case 0x36:
apb_address = 1929;
break;
case 0x37:
apb_address = 1930;
break;
case 0x38:
apb_address = 1931;
break;
case 0x39:
apb_address = 1932;
break;
case 0x2a:
apb_address = 1935;
break;
case 0x2b:
apb_address = 1936;
break;
case 0x2c:
apb_address = 1937;
break;
case 0x2d:
apb_address = 1938;
break;
case 0x2e:
apb_address = 1939;
break;
case 0x2f:
apb_address = 1940;
break;
case 0x30:
apb_address = 1941;
break;
case 0x31:
apb_address = 1942;
break;
case 0x32:
apb_address = 1943;
break;
case 0x3e:
apb_address = 1944;
break;
case 0x3f:
apb_address = 1945;
break;
case 0x40:
apb_address = 1948;
break;
case 0x25:
apb_address = 936;
break;
case 0x26:
apb_address = 937;
break;
case 0x27:
apb_address = 938;
break;
case 0x28:
apb_address = 939;
break;
case 0x1d:
/* get sad sel request */
i = ((dib8000_read_word(state, 921) >> 12)&0x3);
word = dib8000_read_word(state, 924+i);
msg[1].buf[0] = (word >> 8) & 0xff;
msg[1].buf[1] = (word) & 0xff;
return num;
case 0x1f:
if (num == 1) { /* write */
word = (u16) ((msg[0].buf[1] << 8) |
msg[0].buf[2]);
/* in the VGAMODE Sel are located on bit 0/1 */
word &= 0x3;
word = (dib8000_read_word(state, 921) &
~(3<<12)) | (word<<12);
/* Set the proper input */
dib8000_write_word(state, 921, word);
return num;
}
}
if (apb_address != 0) /* R/W access via APB */
return dib8096p_rw_on_apb(i2c_adap, msg, num, apb_address);
else /* R/W access via SERPAR */
return dib8096p_tuner_rw_serpar(i2c_adap, msg, num);
return 0;
}
static u32 dib8096p_i2c_func(struct i2c_adapter *adapter)
{
return I2C_FUNC_I2C;
}
static const struct i2c_algorithm dib8096p_tuner_xfer_algo = {
.master_xfer = dib8096p_tuner_xfer,
.functionality = dib8096p_i2c_func,
};
static struct i2c_adapter *dib8096p_get_i2c_tuner(struct dvb_frontend *fe)
{
struct dib8000_state *st = fe->demodulator_priv;
return &st->dib8096p_tuner_adap;
}
static int dib8096p_tuner_sleep(struct dvb_frontend *fe, int onoff)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 en_cur_state;
dprintk("sleep dib8096p: %d\n", onoff);
en_cur_state = dib8000_read_word(state, 1922);
/* LNAs and MIX are ON and therefore it is a valid configuration */
if (en_cur_state > 0xff)
state->tuner_enable = en_cur_state ;
if (onoff)
en_cur_state &= 0x00ff;
else {
if (state->tuner_enable != 0)
en_cur_state = state->tuner_enable;
}
dib8000_write_word(state, 1922, en_cur_state);
return 0;
}
static const s32 lut_1000ln_mant[] =
{
908, 7003, 7090, 7170, 7244, 7313, 7377, 7438, 7495, 7549, 7600
};
static s32 dib8000_get_adc_power(struct dvb_frontend *fe, u8 mode)
{
struct dib8000_state *state = fe->demodulator_priv;
u32 ix = 0, tmp_val = 0, exp = 0, mant = 0;
s32 val;
val = dib8000_read32(state, 384);
if (mode) {
tmp_val = val;
while (tmp_val >>= 1)
exp++;
mant = (val * 1000 / (1<<exp));
ix = (u8)((mant-1000)/100); /* index of the LUT */
val = (lut_1000ln_mant[ix] + 693*(exp-20) - 6908);
val = (val*256)/1000;
}
return val;
}
static int dib8090p_get_dc_power(struct dvb_frontend *fe, u8 IQ)
{
struct dib8000_state *state = fe->demodulator_priv;
int val = 0;
switch (IQ) {
case 1:
val = dib8000_read_word(state, 403);
break;
case 0:
val = dib8000_read_word(state, 404);
break;
}
if (val & 0x200)
val -= 1024;
return val;
}
static void dib8000_update_timf(struct dib8000_state *state)
{
u32 timf = state->timf = dib8000_read32(state, 435);
dib8000_write_word(state, 29, (u16) (timf >> 16));
dib8000_write_word(state, 30, (u16) (timf & 0xffff));
dprintk("Updated timing frequency: %d (default: %d)\n", state->timf, state->timf_default);
}
static u32 dib8000_ctrl_timf(struct dvb_frontend *fe, uint8_t op, uint32_t timf)
{
struct dib8000_state *state = fe->demodulator_priv;
switch (op) {
case DEMOD_TIMF_SET:
state->timf = timf;
break;
case DEMOD_TIMF_UPDATE:
dib8000_update_timf(state);
break;
case DEMOD_TIMF_GET:
break;
}
dib8000_set_bandwidth(state->fe[0], 6000);
return state->timf;
}
static const u16 adc_target_16dB[11] = {
7250, 7238, 7264, 7309, 7338, 7382, 7427, 7456, 7500, 7544, 7574
};
static const u8 permu_seg[] = { 6, 5, 7, 4, 8, 3, 9, 2, 10, 1, 11, 0, 12 };
static u16 dib8000_set_layer(struct dib8000_state *state, u8 layer_index, u16 max_constellation)
{
u8 cr, constellation, time_intlv;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
switch (c->layer[layer_index].modulation) {
case DQPSK:
constellation = 0;
break;
case QPSK:
constellation = 1;
break;
case QAM_16:
constellation = 2;
break;
case QAM_64:
default:
constellation = 3;
break;
}
switch (c->layer[layer_index].fec) {
case FEC_1_2:
cr = 1;
break;
case FEC_2_3:
cr = 2;
break;
case FEC_3_4:
cr = 3;
break;
case FEC_5_6:
cr = 5;
break;
case FEC_7_8:
default:
cr = 7;
break;
}
time_intlv = fls(c->layer[layer_index].interleaving);
if (time_intlv > 3 && !(time_intlv == 4 && c->isdbt_sb_mode == 1))
time_intlv = 0;
dib8000_write_word(state, 2 + layer_index, (constellation << 10) | ((c->layer[layer_index].segment_count & 0xf) << 6) | (cr << 3) | time_intlv);
if (c->layer[layer_index].segment_count > 0) {
switch (max_constellation) {
case DQPSK:
case QPSK:
if (c->layer[layer_index].modulation == QAM_16 || c->layer[layer_index].modulation == QAM_64)
max_constellation = c->layer[layer_index].modulation;
break;
case QAM_16:
if (c->layer[layer_index].modulation == QAM_64)
max_constellation = c->layer[layer_index].modulation;
break;
}
}
return max_constellation;
}
static const u16 adp_Q64[4] = {0x0148, 0xfff0, 0x00a4, 0xfff8}; /* P_adp_regul_cnt 0.04, P_adp_noise_cnt -0.002, P_adp_regul_ext 0.02, P_adp_noise_ext -0.001 */
static const u16 adp_Q16[4] = {0x023d, 0xffdf, 0x00a4, 0xfff0}; /* P_adp_regul_cnt 0.07, P_adp_noise_cnt -0.004, P_adp_regul_ext 0.02, P_adp_noise_ext -0.002 */
static const u16 adp_Qdefault[4] = {0x099a, 0xffae, 0x0333, 0xfff8}; /* P_adp_regul_cnt 0.3, P_adp_noise_cnt -0.01, P_adp_regul_ext 0.1, P_adp_noise_ext -0.002 */
static u16 dib8000_adp_fine_tune(struct dib8000_state *state, u16 max_constellation)
{
u16 i, ana_gain = 0;
const u16 *adp;
/* channel estimation fine configuration */
switch (max_constellation) {
case QAM_64:
ana_gain = 0x7;
adp = &adp_Q64[0];
break;
case QAM_16:
ana_gain = 0x7;
adp = &adp_Q16[0];
break;
default:
ana_gain = 0;
adp = &adp_Qdefault[0];
break;
}
for (i = 0; i < 4; i++)
dib8000_write_word(state, 215 + i, adp[i]);
return ana_gain;
}
static void dib8000_update_ana_gain(struct dib8000_state *state, u16 ana_gain)
{
u16 i;
dib8000_write_word(state, 116, ana_gain);
/* update ADC target depending on ana_gain */
if (ana_gain) { /* set -16dB ADC target for ana_gain=-1 */
for (i = 0; i < 10; i++)
dib8000_write_word(state, 80 + i, adc_target_16dB[i]);
} else { /* set -22dB ADC target for ana_gain=0 */
for (i = 0; i < 10; i++)
dib8000_write_word(state, 80 + i, adc_target_16dB[i] - 355);
}
}
static void dib8000_load_ana_fe_coefs(struct dib8000_state *state, const s16 *ana_fe)
{
u16 mode = 0;
if (state->isdbt_cfg_loaded == 0)
for (mode = 0; mode < 24; mode++)
dib8000_write_word(state, 117 + mode, ana_fe[mode]);
}
static const u16 lut_prbs_2k[14] = {
0, 0x423, 0x009, 0x5C7, 0x7A6, 0x3D8, 0x527, 0x7FF, 0x79B, 0x3D6, 0x3A2, 0x53B, 0x2F4, 0x213
};
static const u16 lut_prbs_4k[14] = {
0, 0x208, 0x0C3, 0x7B9, 0x423, 0x5C7, 0x3D8, 0x7FF, 0x3D6, 0x53B, 0x213, 0x029, 0x0D0, 0x48E
};
static const u16 lut_prbs_8k[14] = {
0, 0x740, 0x069, 0x7DD, 0x208, 0x7B9, 0x5C7, 0x7FF, 0x53B, 0x029, 0x48E, 0x4C4, 0x367, 0x684
};
static u16 dib8000_get_init_prbs(struct dib8000_state *state, u16 subchannel)
{
int sub_channel_prbs_group = 0;
sub_channel_prbs_group = (subchannel / 3) + 1;
dprintk("sub_channel_prbs_group = %d , subchannel =%d prbs = 0x%04x\n", sub_channel_prbs_group, subchannel, lut_prbs_8k[sub_channel_prbs_group]);
switch (state->fe[0]->dtv_property_cache.transmission_mode) {
case TRANSMISSION_MODE_2K:
return lut_prbs_2k[sub_channel_prbs_group];
case TRANSMISSION_MODE_4K:
return lut_prbs_4k[sub_channel_prbs_group];
default:
case TRANSMISSION_MODE_8K:
return lut_prbs_8k[sub_channel_prbs_group];
}
}
static void dib8000_set_13seg_channel(struct dib8000_state *state)
{
u16 i;
u16 coff_pow = 0x2800;
state->seg_mask = 0x1fff; /* All 13 segments enabled */
/* ---- COFF ---- Carloff, the most robust --- */
if (state->isdbt_cfg_loaded == 0) { /* if not Sound Broadcasting mode : put default values for 13 segments */
dib8000_write_word(state, 180, (16 << 6) | 9);
dib8000_write_word(state, 187, (4 << 12) | (8 << 5) | 0x2);
coff_pow = 0x2800;
for (i = 0; i < 6; i++)
dib8000_write_word(state, 181+i, coff_pow);
/* P_ctrl_corm_thres4pre_freq_inh=1, P_ctrl_pre_freq_mode_sat=1 */
/* P_ctrl_pre_freq_mode_sat=1, P_ctrl_pre_freq_inh=0, P_ctrl_pre_freq_step = 3, P_pre_freq_win_len=1 */
dib8000_write_word(state, 338, (1 << 12) | (1 << 10) | (0 << 9) | (3 << 5) | 1);
/* P_ctrl_pre_freq_win_len=8, P_ctrl_pre_freq_thres_lockin=6 */
dib8000_write_word(state, 340, (8 << 6) | (6 << 0));
/* P_ctrl_pre_freq_thres_lockout=4, P_small_use_tmcc/ac/cp=1 */
dib8000_write_word(state, 341, (4 << 3) | (1 << 2) | (1 << 1) | (1 << 0));
dib8000_write_word(state, 228, 0); /* default value */
dib8000_write_word(state, 265, 31); /* default value */
dib8000_write_word(state, 205, 0x200f); /* init value */
}
/*
* make the cpil_coff_lock more robust but slower p_coff_winlen
* 6bits; p_coff_thres_lock 6bits (for coff lock if needed)
*/
if (state->cfg.pll->ifreq == 0)
dib8000_write_word(state, 266, ~state->seg_mask | state->seg_diff_mask | 0x40); /* P_equal_noise_seg_inh */
dib8000_load_ana_fe_coefs(state, ana_fe_coeff_13seg);
}
static void dib8000_set_subchannel_prbs(struct dib8000_state *state, u16 init_prbs)
{
u16 reg_1;
reg_1 = dib8000_read_word(state, 1);
dib8000_write_word(state, 1, (init_prbs << 2) | (reg_1 & 0x3)); /* ADDR 1 */
}
static void dib8000_small_fine_tune(struct dib8000_state *state)
{
u16 i;
const s16 *ncoeff;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
dib8000_write_word(state, 352, state->seg_diff_mask);
dib8000_write_word(state, 353, state->seg_mask);
/* P_small_coef_ext_enable=ISDB-Tsb, P_small_narrow_band=ISDB-Tsb, P_small_last_seg=13, P_small_offset_num_car=5 */
dib8000_write_word(state, 351, (c->isdbt_sb_mode << 9) | (c->isdbt_sb_mode << 8) | (13 << 4) | 5);
if (c->isdbt_sb_mode) {
/* ---- SMALL ---- */
switch (c->transmission_mode) {
case TRANSMISSION_MODE_2K:
if (c->isdbt_partial_reception == 0) { /* 1-seg */
if (c->layer[0].modulation == DQPSK) /* DQPSK */
ncoeff = coeff_2k_sb_1seg_dqpsk;
else /* QPSK or QAM */
ncoeff = coeff_2k_sb_1seg;
} else { /* 3-segments */
if (c->layer[0].modulation == DQPSK) { /* DQPSK on central segment */
if (c->layer[1].modulation == DQPSK) /* DQPSK on external segments */
ncoeff = coeff_2k_sb_3seg_0dqpsk_1dqpsk;
else /* QPSK or QAM on external segments */
ncoeff = coeff_2k_sb_3seg_0dqpsk;
} else { /* QPSK or QAM on central segment */
if (c->layer[1].modulation == DQPSK) /* DQPSK on external segments */
ncoeff = coeff_2k_sb_3seg_1dqpsk;
else /* QPSK or QAM on external segments */
ncoeff = coeff_2k_sb_3seg;
}
}
break;
case TRANSMISSION_MODE_4K:
if (c->isdbt_partial_reception == 0) { /* 1-seg */
if (c->layer[0].modulation == DQPSK) /* DQPSK */
ncoeff = coeff_4k_sb_1seg_dqpsk;
else /* QPSK or QAM */
ncoeff = coeff_4k_sb_1seg;
} else { /* 3-segments */
if (c->layer[0].modulation == DQPSK) { /* DQPSK on central segment */
if (c->layer[1].modulation == DQPSK) /* DQPSK on external segments */
ncoeff = coeff_4k_sb_3seg_0dqpsk_1dqpsk;
else /* QPSK or QAM on external segments */
ncoeff = coeff_4k_sb_3seg_0dqpsk;
} else { /* QPSK or QAM on central segment */
if (c->layer[1].modulation == DQPSK) /* DQPSK on external segments */
ncoeff = coeff_4k_sb_3seg_1dqpsk;
else /* QPSK or QAM on external segments */
ncoeff = coeff_4k_sb_3seg;
}
}
break;
case TRANSMISSION_MODE_AUTO:
case TRANSMISSION_MODE_8K:
default:
if (c->isdbt_partial_reception == 0) { /* 1-seg */
if (c->layer[0].modulation == DQPSK) /* DQPSK */
ncoeff = coeff_8k_sb_1seg_dqpsk;
else /* QPSK or QAM */
ncoeff = coeff_8k_sb_1seg;
} else { /* 3-segments */
if (c->layer[0].modulation == DQPSK) { /* DQPSK on central segment */
if (c->layer[1].modulation == DQPSK) /* DQPSK on external segments */
ncoeff = coeff_8k_sb_3seg_0dqpsk_1dqpsk;
else /* QPSK or QAM on external segments */
ncoeff = coeff_8k_sb_3seg_0dqpsk;
} else { /* QPSK or QAM on central segment */
if (c->layer[1].modulation == DQPSK) /* DQPSK on external segments */
ncoeff = coeff_8k_sb_3seg_1dqpsk;
else /* QPSK or QAM on external segments */
ncoeff = coeff_8k_sb_3seg;
}
}
break;
}
for (i = 0; i < 8; i++)
dib8000_write_word(state, 343 + i, ncoeff[i]);
}
}
static const u16 coff_thres_1seg[3] = {300, 150, 80};
static const u16 coff_thres_3seg[3] = {350, 300, 250};
static void dib8000_set_sb_channel(struct dib8000_state *state)
{
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
const u16 *coff;
u16 i;
if (c->transmission_mode == TRANSMISSION_MODE_2K || c->transmission_mode == TRANSMISSION_MODE_4K) {
dib8000_write_word(state, 219, dib8000_read_word(state, 219) | 0x1); /* adp_pass =1 */
dib8000_write_word(state, 190, dib8000_read_word(state, 190) | (0x1 << 14)); /* pha3_force_pha_shift = 1 */
} else {
dib8000_write_word(state, 219, dib8000_read_word(state, 219) & 0xfffe); /* adp_pass =0 */
dib8000_write_word(state, 190, dib8000_read_word(state, 190) & 0xbfff); /* pha3_force_pha_shift = 0 */
}
if (c->isdbt_partial_reception == 1) /* 3-segments */
state->seg_mask = 0x00E0;
else /* 1-segment */
state->seg_mask = 0x0040;
dib8000_write_word(state, 268, (dib8000_read_word(state, 268) & 0xF9FF) | 0x0200);
/* ---- COFF ---- Carloff, the most robust --- */
/* P_coff_cpil_alpha=4, P_coff_inh=0, P_coff_cpil_winlen=64, P_coff_narrow_band=1, P_coff_square_val=1, P_coff_one_seg=~partial_rcpt, P_coff_use_tmcc=1, P_coff_use_ac=1 */
dib8000_write_word(state, 187, (4 << 12) | (0 << 11) | (63 << 5) | (0x3 << 3) | ((~c->isdbt_partial_reception & 1) << 2) | 0x3);
dib8000_write_word(state, 340, (16 << 6) | (8 << 0)); /* P_ctrl_pre_freq_win_len=16, P_ctrl_pre_freq_thres_lockin=8 */
dib8000_write_word(state, 341, (6 << 3) | (1 << 2) | (1 << 1) | (1 << 0));/* P_ctrl_pre_freq_thres_lockout=6, P_small_use_tmcc/ac/cp=1 */
/* Sound Broadcasting mode 1 seg */
if (c->isdbt_partial_reception == 0) {
/* P_coff_winlen=63, P_coff_thres_lock=15, P_coff_one_seg_width = (P_mode == 3) , P_coff_one_seg_sym = (P_mode-1) */
if (state->mode == 3)
dib8000_write_word(state, 180, 0x1fcf | ((state->mode - 1) << 14));
else
dib8000_write_word(state, 180, 0x0fcf | ((state->mode - 1) << 14));
/* P_ctrl_corm_thres4pre_freq_inh=1,P_ctrl_pre_freq_mode_sat=1, P_ctrl_pre_freq_inh=0, P_ctrl_pre_freq_step = 5, P_pre_freq_win_len=4 */
dib8000_write_word(state, 338, (1 << 12) | (1 << 10) | (0 << 9) | (5 << 5) | 4);
coff = &coff_thres_1seg[0];
} else { /* Sound Broadcasting mode 3 seg */
dib8000_write_word(state, 180, 0x1fcf | (1 << 14));
/* P_ctrl_corm_thres4pre_freq_inh = 1, P_ctrl_pre_freq_mode_sat=1, P_ctrl_pre_freq_inh=0, P_ctrl_pre_freq_step = 4, P_pre_freq_win_len=4 */
dib8000_write_word(state, 338, (1 << 12) | (1 << 10) | (0 << 9) | (4 << 5) | 4);
coff = &coff_thres_3seg[0];
}
dib8000_write_word(state, 228, 1); /* P_2d_mode_byp=1 */
dib8000_write_word(state, 205, dib8000_read_word(state, 205) & 0xfff0); /* P_cspu_win_cut = 0 */
if (c->isdbt_partial_reception == 0 && c->transmission_mode == TRANSMISSION_MODE_2K)
dib8000_write_word(state, 265, 15); /* P_equal_noise_sel = 15 */
/* Write COFF thres */
for (i = 0 ; i < 3; i++) {
dib8000_write_word(state, 181+i, coff[i]);
dib8000_write_word(state, 184+i, coff[i]);
}
/*
* make the cpil_coff_lock more robust but slower p_coff_winlen
* 6bits; p_coff_thres_lock 6bits (for coff lock if needed)
*/
dib8000_write_word(state, 266, ~state->seg_mask | state->seg_diff_mask); /* P_equal_noise_seg_inh */
if (c->isdbt_partial_reception == 0)
dib8000_write_word(state, 178, 64); /* P_fft_powrange = 64 */
else
dib8000_write_word(state, 178, 32); /* P_fft_powrange = 32 */
}
static void dib8000_set_isdbt_common_channel(struct dib8000_state *state, u8 seq, u8 autosearching)
{
u16 p_cfr_left_edge = 0, p_cfr_right_edge = 0;
u16 tmcc_pow = 0, ana_gain = 0, tmp = 0, i = 0, nbseg_diff = 0 ;
u16 max_constellation = DQPSK;
int init_prbs;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
if (autosearching)
c->isdbt_partial_reception = 1;
/* P_mode */
dib8000_write_word(state, 10, (seq << 4));
/* init mode */
state->mode = fft_to_mode(state);
/* set guard */
tmp = dib8000_read_word(state, 1);
dib8000_write_word(state, 1, (tmp&0xfffc) | (c->guard_interval & 0x3));
dib8000_write_word(state, 274, (dib8000_read_word(state, 274) & 0xffcf) | ((c->isdbt_partial_reception & 1) << 5) | ((c->isdbt_sb_mode & 1) << 4));
/* signal optimization parameter */
if (c->isdbt_partial_reception) {
state->seg_diff_mask = (c->layer[0].modulation == DQPSK) << permu_seg[0];
for (i = 1; i < 3; i++)
nbseg_diff += (c->layer[i].modulation == DQPSK) * c->layer[i].segment_count;
for (i = 0; i < nbseg_diff; i++)
state->seg_diff_mask |= 1 << permu_seg[i+1];
} else {
for (i = 0; i < 3; i++)
nbseg_diff += (c->layer[i].modulation == DQPSK) * c->layer[i].segment_count;
for (i = 0; i < nbseg_diff; i++)
state->seg_diff_mask |= 1 << permu_seg[i];
}
if (state->seg_diff_mask)
dib8000_write_word(state, 268, (dib8000_read_word(state, 268) & 0xF9FF) | 0x0200);
else
dib8000_write_word(state, 268, (2 << 9) | 39); /*init value */
for (i = 0; i < 3; i++)
max_constellation = dib8000_set_layer(state, i, max_constellation);
if (autosearching == 0) {
state->layer_b_nb_seg = c->layer[1].segment_count;
state->layer_c_nb_seg = c->layer[2].segment_count;
}
/* WRITE: Mode & Diff mask */
dib8000_write_word(state, 0, (state->mode << 13) | state->seg_diff_mask);
state->differential_constellation = (state->seg_diff_mask != 0);
/* channel estimation fine configuration */
ana_gain = dib8000_adp_fine_tune(state, max_constellation);
/* update ana_gain depending on max constellation */
dib8000_update_ana_gain(state, ana_gain);
/* ---- ANA_FE ---- */
if (c->isdbt_partial_reception) /* 3-segments */
dib8000_load_ana_fe_coefs(state, ana_fe_coeff_3seg);
else
dib8000_load_ana_fe_coefs(state, ana_fe_coeff_1seg); /* 1-segment */
/* TSB or ISDBT ? apply it now */
if (c->isdbt_sb_mode) {
dib8000_set_sb_channel(state);
if (c->isdbt_sb_subchannel < 14)
init_prbs = dib8000_get_init_prbs(state, c->isdbt_sb_subchannel);
else
init_prbs = 0;
} else {
dib8000_set_13seg_channel(state);
init_prbs = 0xfff;
}
/* SMALL */
dib8000_small_fine_tune(state);
dib8000_set_subchannel_prbs(state, init_prbs);
/* ---- CHAN_BLK ---- */
for (i = 0; i < 13; i++) {
if ((((~state->seg_diff_mask) >> i) & 1) == 1) {
p_cfr_left_edge += (1 << i) * ((i == 0) || ((((state->seg_mask & (~state->seg_diff_mask)) >> (i - 1)) & 1) == 0));
p_cfr_right_edge += (1 << i) * ((i == 12) || ((((state->seg_mask & (~state->seg_diff_mask)) >> (i + 1)) & 1) == 0));
}
}
dib8000_write_word(state, 222, p_cfr_left_edge); /* p_cfr_left_edge */
dib8000_write_word(state, 223, p_cfr_right_edge); /* p_cfr_right_edge */
/* "P_cspu_left_edge" & "P_cspu_right_edge" not used => do not care */
dib8000_write_word(state, 189, ~state->seg_mask | state->seg_diff_mask); /* P_lmod4_seg_inh */
dib8000_write_word(state, 192, ~state->seg_mask | state->seg_diff_mask); /* P_pha3_seg_inh */
dib8000_write_word(state, 225, ~state->seg_mask | state->seg_diff_mask); /* P_tac_seg_inh */
if (!autosearching)
dib8000_write_word(state, 288, (~state->seg_mask | state->seg_diff_mask) & 0x1fff); /* P_tmcc_seg_eq_inh */
else
dib8000_write_word(state, 288, 0x1fff); /*disable equalisation of the tmcc when autosearch to be able to find the DQPSK channels. */
dib8000_write_word(state, 211, state->seg_mask & (~state->seg_diff_mask)); /* P_des_seg_enabled */
dib8000_write_word(state, 287, ~state->seg_mask | 0x1000); /* P_tmcc_seg_inh */
dib8000_write_word(state, 178, 32); /* P_fft_powrange = 32 */
/* ---- TMCC ---- */
for (i = 0; i < 3; i++)
tmcc_pow += (((c->layer[i].modulation == DQPSK) * 4 + 1) * c->layer[i].segment_count) ;
/* Quantif of "P_tmcc_dec_thres_?k" is (0, 5+mode, 9); */
/* Threshold is set at 1/4 of max power. */
tmcc_pow *= (1 << (9-2));
dib8000_write_word(state, 290, tmcc_pow); /* P_tmcc_dec_thres_2k */
dib8000_write_word(state, 291, tmcc_pow); /* P_tmcc_dec_thres_4k */
dib8000_write_word(state, 292, tmcc_pow); /* P_tmcc_dec_thres_8k */
/*dib8000_write_word(state, 287, (1 << 13) | 0x1000 ); */
/* ---- PHA3 ---- */
if (state->isdbt_cfg_loaded == 0)
dib8000_write_word(state, 250, 3285); /* p_2d_hspeed_thr0 */
state->isdbt_cfg_loaded = 0;
}
static u32 dib8000_wait_lock(struct dib8000_state *state, u32 internal,
u32 wait0_ms, u32 wait1_ms, u32 wait2_ms)
{
u32 value = 0; /* P_search_end0 wait time */
u16 reg = 11; /* P_search_end0 start addr */
for (reg = 11; reg < 16; reg += 2) {
if (reg == 11) {
if (state->revision == 0x8090)
value = internal * wait1_ms;
else
value = internal * wait0_ms;
} else if (reg == 13)
value = internal * wait1_ms;
else if (reg == 15)
value = internal * wait2_ms;
dib8000_write_word(state, reg, (u16)((value >> 16) & 0xffff));
dib8000_write_word(state, (reg + 1), (u16)(value & 0xffff));
}
return value;
}
static int dib8000_autosearch_start(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
u8 slist = 0;
u32 value, internal = state->cfg.pll->internal;
if (state->revision == 0x8090)
internal = dib8000_read32(state, 23) / 1000;
if ((state->revision >= 0x8002) &&
(state->autosearch_state == AS_SEARCHING_FFT)) {
dib8000_write_word(state, 37, 0x0065); /* P_ctrl_pha_off_max default values */
dib8000_write_word(state, 116, 0x0000); /* P_ana_gain to 0 */
dib8000_write_word(state, 0, (dib8000_read_word(state, 0) & 0x1fff) | (0 << 13) | (1 << 15)); /* P_mode = 0, P_restart_search=1 */
dib8000_write_word(state, 1, (dib8000_read_word(state, 1) & 0xfffc) | 0); /* P_guard = 0 */
dib8000_write_word(state, 6, 0); /* P_lock0_mask = 0 */
dib8000_write_word(state, 7, 0); /* P_lock1_mask = 0 */
dib8000_write_word(state, 8, 0); /* P_lock2_mask = 0 */
dib8000_write_word(state, 10, (dib8000_read_word(state, 10) & 0x200) | (16 << 4) | (0 << 0)); /* P_search_list=16, P_search_maxtrial=0 */
if (state->revision == 0x8090)
value = dib8000_wait_lock(state, internal, 10, 10, 10); /* time in ms configure P_search_end0 P_search_end1 P_search_end2 */
else
value = dib8000_wait_lock(state, internal, 20, 20, 20); /* time in ms configure P_search_end0 P_search_end1 P_search_end2 */
dib8000_write_word(state, 17, 0);
dib8000_write_word(state, 18, 200); /* P_search_rstst = 200 */
dib8000_write_word(state, 19, 0);
dib8000_write_word(state, 20, 400); /* P_search_rstend = 400 */
dib8000_write_word(state, 21, (value >> 16) & 0xffff); /* P_search_checkst */
dib8000_write_word(state, 22, value & 0xffff);
if (state->revision == 0x8090)
dib8000_write_word(state, 32, (dib8000_read_word(state, 32) & 0xf0ff) | (0 << 8)); /* P_corm_alpha = 0 */
else
dib8000_write_word(state, 32, (dib8000_read_word(state, 32) & 0xf0ff) | (9 << 8)); /* P_corm_alpha = 3 */
dib8000_write_word(state, 355, 2); /* P_search_param_max = 2 */
/* P_search_param_select = (1 | 1<<4 | 1 << 8) */
dib8000_write_word(state, 356, 0);
dib8000_write_word(state, 357, 0x111);
dib8000_write_word(state, 770, (dib8000_read_word(state, 770) & 0xdfff) | (1 << 13)); /* P_restart_ccg = 1 */
dib8000_write_word(state, 770, (dib8000_read_word(state, 770) & 0xdfff) | (0 << 13)); /* P_restart_ccg = 0 */
dib8000_write_word(state, 0, (dib8000_read_word(state, 0) & 0x7ff) | (0 << 15) | (1 << 13)); /* P_restart_search = 0; */
} else if ((state->revision >= 0x8002) &&
(state->autosearch_state == AS_SEARCHING_GUARD)) {
c->transmission_mode = TRANSMISSION_MODE_8K;
c->guard_interval = GUARD_INTERVAL_1_8;
c->inversion = 0;
c->layer[0].modulation = QAM_64;
c->layer[0].fec = FEC_2_3;
c->layer[0].interleaving = 0;
c->layer[0].segment_count = 13;
slist = 16;
c->transmission_mode = state->found_nfft;
dib8000_set_isdbt_common_channel(state, slist, 1);
/* set lock_mask values */
dib8000_write_word(state, 6, 0x4);
if (state->revision == 0x8090)
dib8000_write_word(state, 7, ((1 << 12) | (1 << 11) | (1 << 10)));/* tmcc_dec_lock, tmcc_sync_lock, tmcc_data_lock, tmcc_bch_uncor */
else
dib8000_write_word(state, 7, 0x8);
dib8000_write_word(state, 8, 0x1000);
/* set lock_mask wait time values */
if (state->revision == 0x8090)
dib8000_wait_lock(state, internal, 50, 100, 1000); /* time in ms configure P_search_end0 P_search_end1 P_search_end2 */
else
dib8000_wait_lock(state, internal, 50, 200, 1000); /* time in ms configure P_search_end0 P_search_end1 P_search_end2 */
dib8000_write_word(state, 355, 3); /* P_search_param_max = 3 */
/* P_search_param_select = 0xf; look for the 4 different guard intervals */
dib8000_write_word(state, 356, 0);
dib8000_write_word(state, 357, 0xf);
value = dib8000_read_word(state, 0);
dib8000_write_word(state, 0, (u16)((1 << 15) | value));
dib8000_read_word(state, 1284); /* reset the INT. n_irq_pending */
dib8000_write_word(state, 0, (u16)value);
} else {
c->inversion = 0;
c->layer[0].modulation = QAM_64;
c->layer[0].fec = FEC_2_3;
c->layer[0].interleaving = 0;
c->layer[0].segment_count = 13;
if (!c->isdbt_sb_mode)
c->layer[0].segment_count = 13;
/* choose the right list, in sb, always do everything */
if (c->isdbt_sb_mode) {
slist = 7;
dib8000_write_word(state, 0, (dib8000_read_word(state, 0) & 0x9fff) | (1 << 13));
} else {
if (c->guard_interval == GUARD_INTERVAL_AUTO) {
if (c->transmission_mode == TRANSMISSION_MODE_AUTO) {
c->transmission_mode = TRANSMISSION_MODE_8K;
c->guard_interval = GUARD_INTERVAL_1_8;
slist = 7;
dib8000_write_word(state, 0, (dib8000_read_word(state, 0) & 0x9fff) | (1 << 13)); /* P_mode = 1 to have autosearch start ok with mode2 */
} else {
c->guard_interval = GUARD_INTERVAL_1_8;
slist = 3;
}
} else {
if (c->transmission_mode == TRANSMISSION_MODE_AUTO) {
c->transmission_mode = TRANSMISSION_MODE_8K;
slist = 2;
dib8000_write_word(state, 0, (dib8000_read_word(state, 0) & 0x9fff) | (1 << 13)); /* P_mode = 1 */
} else
slist = 0;
}
}
dprintk("Using list for autosearch : %d\n", slist);
dib8000_set_isdbt_common_channel(state, slist, 1);
/* set lock_mask values */
dib8000_write_word(state, 6, 0x4);
if (state->revision == 0x8090)
dib8000_write_word(state, 7, (1 << 12) | (1 << 11) | (1 << 10));
else
dib8000_write_word(state, 7, 0x8);
dib8000_write_word(state, 8, 0x1000);
/* set lock_mask wait time values */
if (state->revision == 0x8090)
dib8000_wait_lock(state, internal, 50, 200, 1000); /* time in ms configure P_search_end0 P_search_end1 P_search_end2 */
else
dib8000_wait_lock(state, internal, 50, 100, 1000); /* time in ms configure P_search_end0 P_search_end1 P_search_end2 */
value = dib8000_read_word(state, 0);
dib8000_write_word(state, 0, (u16)((1 << 15) | value));
dib8000_read_word(state, 1284); /* reset the INT. n_irq_pending */
dib8000_write_word(state, 0, (u16)value);
}
return 0;
}
static int dib8000_autosearch_irq(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 irq_pending = dib8000_read_word(state, 1284);
if ((state->revision >= 0x8002) &&
(state->autosearch_state == AS_SEARCHING_FFT)) {
if (irq_pending & 0x1) {
dprintk("dib8000_autosearch_irq: max correlation result available\n");
return 3;
}
} else {
if (irq_pending & 0x1) { /* failed */
dprintk("dib8000_autosearch_irq failed\n");
return 1;
}
if (irq_pending & 0x2) { /* succeeded */
dprintk("dib8000_autosearch_irq succeeded\n");
return 2;
}
}
return 0; // still pending
}
static void dib8000_viterbi_state(struct dib8000_state *state, u8 onoff)
{
u16 tmp;
tmp = dib8000_read_word(state, 771);
if (onoff) /* start P_restart_chd : channel_decoder */
dib8000_write_word(state, 771, tmp & 0xfffd);
else /* stop P_restart_chd : channel_decoder */
dib8000_write_word(state, 771, tmp | (1<<1));
}
static void dib8000_set_dds(struct dib8000_state *state, s32 offset_khz)
{
s16 unit_khz_dds_val;
u32 abs_offset_khz = abs(offset_khz);
u32 dds = state->cfg.pll->ifreq & 0x1ffffff;
u8 invert = !!(state->cfg.pll->ifreq & (1 << 25));
u8 ratio;
if (state->revision == 0x8090) {
ratio = 4;
unit_khz_dds_val = (1<<26) / (dib8000_read32(state, 23) / 1000);
if (offset_khz < 0)
dds = (1 << 26) - (abs_offset_khz * unit_khz_dds_val);
else
dds = (abs_offset_khz * unit_khz_dds_val);
if (invert)
dds = (1<<26) - dds;
} else {
ratio = 2;
unit_khz_dds_val = (u16) (67108864 / state->cfg.pll->internal);
if (offset_khz < 0)
unit_khz_dds_val *= -1;
/* IF tuner */
if (invert)
dds -= abs_offset_khz * unit_khz_dds_val;
else
dds += abs_offset_khz * unit_khz_dds_val;
}
dprintk("setting a DDS frequency offset of %c%dkHz\n", invert ? '-' : ' ', dds / unit_khz_dds_val);
if (abs_offset_khz <= (state->cfg.pll->internal / ratio)) {
/* Max dds offset is the half of the demod freq */
dib8000_write_word(state, 26, invert);
dib8000_write_word(state, 27, (u16)(dds >> 16) & 0x1ff);
dib8000_write_word(state, 28, (u16)(dds & 0xffff));
}
}
static void dib8000_set_frequency_offset(struct dib8000_state *state)
{
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
int i;
u32 current_rf;
int total_dds_offset_khz;
if (state->fe[0]->ops.tuner_ops.get_frequency)
state->fe[0]->ops.tuner_ops.get_frequency(state->fe[0], &current_rf);
else
current_rf = c->frequency;
current_rf /= 1000;
total_dds_offset_khz = (int)current_rf - (int)c->frequency / 1000;
if (c->isdbt_sb_mode) {
state->subchannel = c->isdbt_sb_subchannel;
i = dib8000_read_word(state, 26) & 1; /* P_dds_invspec */
dib8000_write_word(state, 26, c->inversion ^ i);
if (state->cfg.pll->ifreq == 0) { /* low if tuner */
if ((c->inversion ^ i) == 0)
dib8000_write_word(state, 26, dib8000_read_word(state, 26) | 1);
} else {
if ((c->inversion ^ i) == 0)
total_dds_offset_khz *= -1;
}
}
dprintk("%dkhz tuner offset (frequency = %dHz & current_rf = %dHz) total_dds_offset_hz = %d\n", c->frequency - current_rf, c->frequency, current_rf, total_dds_offset_khz);
/* apply dds offset now */
dib8000_set_dds(state, total_dds_offset_khz);
}
static u16 LUT_isdbt_symbol_duration[4] = { 26, 101, 63 };
static u32 dib8000_get_symbol_duration(struct dib8000_state *state)
{
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
u16 i;
switch (c->transmission_mode) {
case TRANSMISSION_MODE_2K:
i = 0;
break;
case TRANSMISSION_MODE_4K:
i = 2;
break;
default:
case TRANSMISSION_MODE_AUTO:
case TRANSMISSION_MODE_8K:
i = 1;
break;
}
return (LUT_isdbt_symbol_duration[i] / (c->bandwidth_hz / 1000)) + 1;
}
static void dib8000_set_isdbt_loop_params(struct dib8000_state *state, enum param_loop_step loop_step)
{
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
u16 reg_32 = 0, reg_37 = 0;
switch (loop_step) {
case LOOP_TUNE_1:
if (c->isdbt_sb_mode) {
if (c->isdbt_partial_reception == 0) {
reg_32 = ((11 - state->mode) << 12) | (6 << 8) | 0x40; /* P_timf_alpha = (11-P_mode), P_corm_alpha=6, P_corm_thres=0x40 */
reg_37 = (3 << 5) | (0 << 4) | (10 - state->mode); /* P_ctrl_pha_off_max=3 P_ctrl_sfreq_inh =0 P_ctrl_sfreq_step = (10-P_mode) */
} else { /* Sound Broadcasting mode 3 seg */
reg_32 = ((10 - state->mode) << 12) | (6 << 8) | 0x60; /* P_timf_alpha = (10-P_mode), P_corm_alpha=6, P_corm_thres=0x60 */
reg_37 = (3 << 5) | (0 << 4) | (9 - state->mode); /* P_ctrl_pha_off_max=3 P_ctrl_sfreq_inh =0 P_ctrl_sfreq_step = (9-P_mode) */
}
} else { /* 13-seg start conf offset loop parameters */
reg_32 = ((9 - state->mode) << 12) | (6 << 8) | 0x80; /* P_timf_alpha = (9-P_mode, P_corm_alpha=6, P_corm_thres=0x80 */
reg_37 = (3 << 5) | (0 << 4) | (8 - state->mode); /* P_ctrl_pha_off_max=3 P_ctrl_sfreq_inh =0 P_ctrl_sfreq_step = 9 */
}
break;
case LOOP_TUNE_2:
if (c->isdbt_sb_mode) {
if (c->isdbt_partial_reception == 0) { /* Sound Broadcasting mode 1 seg */
reg_32 = ((13-state->mode) << 12) | (6 << 8) | 0x40; /* P_timf_alpha = (13-P_mode) , P_corm_alpha=6, P_corm_thres=0x40*/
reg_37 = (12-state->mode) | ((5 + state->mode) << 5);
} else { /* Sound Broadcasting mode 3 seg */
reg_32 = ((12-state->mode) << 12) | (6 << 8) | 0x60; /* P_timf_alpha = (12-P_mode) , P_corm_alpha=6, P_corm_thres=0x60 */
reg_37 = (11-state->mode) | ((5 + state->mode) << 5);
}
} else { /* 13 seg */
reg_32 = ((11-state->mode) << 12) | (6 << 8) | 0x80; /* P_timf_alpha = 8 , P_corm_alpha=6, P_corm_thres=0x80 */
reg_37 = ((5+state->mode) << 5) | (10 - state->mode);
}
break;
}
dib8000_write_word(state, 32, reg_32);
dib8000_write_word(state, 37, reg_37);
}
static void dib8000_demod_restart(struct dib8000_state *state)
{
dib8000_write_word(state, 770, 0x4000);
dib8000_write_word(state, 770, 0x0000);
return;
}
static void dib8000_set_sync_wait(struct dib8000_state *state)
{
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
u16 sync_wait = 64;
/* P_dvsy_sync_wait - reuse mode */
switch (c->transmission_mode) {
case TRANSMISSION_MODE_8K:
sync_wait = 256;
break;
case TRANSMISSION_MODE_4K:
sync_wait = 128;
break;
default:
case TRANSMISSION_MODE_2K:
sync_wait = 64;
break;
}
if (state->cfg.diversity_delay == 0)
sync_wait = (sync_wait * (1 << (c->guard_interval)) * 3) / 2 + 48; /* add 50% SFN margin + compensate for one DVSY-fifo */
else
sync_wait = (sync_wait * (1 << (c->guard_interval)) * 3) / 2 + state->cfg.diversity_delay; /* add 50% SFN margin + compensate for DVSY-fifo */
dib8000_write_word(state, 273, (dib8000_read_word(state, 273) & 0x000f) | (sync_wait << 4));
}
static unsigned long dib8000_get_timeout(struct dib8000_state *state, u32 delay, enum timeout_mode mode)
{
if (mode == SYMBOL_DEPENDENT_ON)
delay *= state->symbol_duration;
return jiffies + usecs_to_jiffies(delay * 100);
}
static s32 dib8000_get_status(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
return state->status;
}
static enum frontend_tune_state dib8000_get_tune_state(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
return state->tune_state;
}
static int dib8000_set_tune_state(struct dvb_frontend *fe, enum frontend_tune_state tune_state)
{
struct dib8000_state *state = fe->demodulator_priv;
state->tune_state = tune_state;
return 0;
}
static int dib8000_tune_restart_from_demod(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
state->status = FE_STATUS_TUNE_PENDING;
state->tune_state = CT_DEMOD_START;
return 0;
}
static u16 dib8000_read_lock(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
if (state->revision == 0x8090)
return dib8000_read_word(state, 570);
return dib8000_read_word(state, 568);
}
static int dib8090p_init_sdram(struct dib8000_state *state)
{
u16 reg = 0;
dprintk("init sdram\n");
reg = dib8000_read_word(state, 274) & 0xfff0;
dib8000_write_word(state, 274, reg | 0x7); /* P_dintlv_delay_ram = 7 because of MobileSdram */
dib8000_write_word(state, 1803, (7 << 2));
reg = dib8000_read_word(state, 1280);
dib8000_write_word(state, 1280, reg | (1 << 2)); /* force restart P_restart_sdram */
dib8000_write_word(state, 1280, reg); /* release restart P_restart_sdram */
return 0;
}
/**
* is_manual_mode - Check if TMCC should be used for parameters settings
* @c: struct dvb_frontend_properties
*
* By default, TMCC table should be used for parameter settings on most
* usercases. However, sometimes it is desirable to lock the demod to
* use the manual parameters.
*
* On manual mode, the current dib8000_tune state machine is very restrict:
* It requires that both per-layer and per-transponder parameters to be
* properly specified, otherwise the device won't lock.
*
* Check if all those conditions are properly satisfied before allowing
* the device to use the manual frequency lock mode.
*/
static int is_manual_mode(struct dtv_frontend_properties *c)
{
int i, n_segs = 0;
/* Use auto mode on DVB-T compat mode */
if (c->delivery_system != SYS_ISDBT)
return 0;
/*
* Transmission mode is only detected on auto mode, currently
*/
if (c->transmission_mode == TRANSMISSION_MODE_AUTO) {
dprintk("transmission mode auto\n");
return 0;
}
/*
* Guard interval is only detected on auto mode, currently
*/
if (c->guard_interval == GUARD_INTERVAL_AUTO) {
dprintk("guard interval auto\n");
return 0;
}
/*
* If no layer is enabled, assume auto mode, as at least one
* layer should be enabled
*/
if (!c->isdbt_layer_enabled) {
dprintk("no layer modulation specified\n");
return 0;
}
/*
* Check if the per-layer parameters aren't auto and
* disable a layer if segment count is 0 or invalid.
*/
for (i = 0; i < 3; i++) {
if (!(c->isdbt_layer_enabled & 1 << i))
continue;
if ((c->layer[i].segment_count > 13) ||
(c->layer[i].segment_count == 0)) {
c->isdbt_layer_enabled &= ~(1 << i);
continue;
}
n_segs += c->layer[i].segment_count;
if ((c->layer[i].modulation == QAM_AUTO) ||
(c->layer[i].fec == FEC_AUTO)) {
dprintk("layer %c has either modulation or FEC auto\n",
'A' + i);
return 0;
}
}
/*
* Userspace specified a wrong number of segments.
* fallback to auto mode.
*/
if (n_segs == 0 || n_segs > 13) {
dprintk("number of segments is invalid\n");
return 0;
}
/* Everything looks ok for manual mode */
return 1;
}
static int dib8000_tune(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
enum frontend_tune_state *tune_state = &state->tune_state;
u16 locks, deeper_interleaver = 0, i;
int ret = 1; /* 1 symbol duration (in 100us unit) delay most of the time */
unsigned long *timeout = &state->timeout;
unsigned long now = jiffies;
#ifdef DIB8000_AGC_FREEZE
u16 agc1, agc2;
#endif
u32 corm[4] = {0, 0, 0, 0};
u8 find_index, max_value;
#if 0
if (*tune_state < CT_DEMOD_STOP)
dprintk("IN: context status = %d, TUNE_STATE %d autosearch step = %u jiffies = %lu\n",
state->channel_parameters_set, *tune_state, state->autosearch_state, now);
#endif
switch (*tune_state) {
case CT_DEMOD_START: /* 30 */
dib8000_reset_stats(fe);
if (state->revision == 0x8090)
dib8090p_init_sdram(state);
state->status = FE_STATUS_TUNE_PENDING;
state->channel_parameters_set = is_manual_mode(c);
dprintk("Tuning channel on %s search mode\n",
state->channel_parameters_set ? "manual" : "auto");
dib8000_viterbi_state(state, 0); /* force chan dec in restart */
/* Layer monitor */
dib8000_write_word(state, 285, dib8000_read_word(state, 285) & 0x60);
dib8000_set_frequency_offset(state);
dib8000_set_bandwidth(fe, c->bandwidth_hz / 1000);
if (state->channel_parameters_set == 0) { /* The channel struct is unknown, search it ! */
#ifdef DIB8000_AGC_FREEZE
if (state->revision != 0x8090) {
state->agc1_max = dib8000_read_word(state, 108);
state->agc1_min = dib8000_read_word(state, 109);
state->agc2_max = dib8000_read_word(state, 110);
state->agc2_min = dib8000_read_word(state, 111);
agc1 = dib8000_read_word(state, 388);
agc2 = dib8000_read_word(state, 389);
dib8000_write_word(state, 108, agc1);
dib8000_write_word(state, 109, agc1);
dib8000_write_word(state, 110, agc2);
dib8000_write_word(state, 111, agc2);
}
#endif
state->autosearch_state = AS_SEARCHING_FFT;
state->found_nfft = TRANSMISSION_MODE_AUTO;
state->found_guard = GUARD_INTERVAL_AUTO;
*tune_state = CT_DEMOD_SEARCH_NEXT;
} else { /* we already know the channel struct so TUNE only ! */
state->autosearch_state = AS_DONE;
*tune_state = CT_DEMOD_STEP_3;
}
state->symbol_duration = dib8000_get_symbol_duration(state);
break;
case CT_DEMOD_SEARCH_NEXT: /* 51 */
dib8000_autosearch_start(fe);
if (state->revision == 0x8090)
ret = 50;
else
ret = 15;
*tune_state = CT_DEMOD_STEP_1;
break;
case CT_DEMOD_STEP_1: /* 31 */
switch (dib8000_autosearch_irq(fe)) {
case 1: /* fail */
state->status = FE_STATUS_TUNE_FAILED;
state->autosearch_state = AS_DONE;
*tune_state = CT_DEMOD_STOP; /* else we are done here */
break;
case 2: /* Success */
state->status = FE_STATUS_FFT_SUCCESS; /* signal to the upper layer, that there was a channel found and the parameters can be read */
*tune_state = CT_DEMOD_STEP_3;
if (state->autosearch_state == AS_SEARCHING_GUARD)
*tune_state = CT_DEMOD_STEP_2;
else
state->autosearch_state = AS_DONE;
break;
case 3: /* Autosearch FFT max correlation endded */
*tune_state = CT_DEMOD_STEP_2;
break;
}
break;
case CT_DEMOD_STEP_2:
switch (state->autosearch_state) {
case AS_SEARCHING_FFT:
/* searching for the correct FFT */
if (state->revision == 0x8090) {
corm[2] = (dib8000_read_word(state, 596) << 16) | (dib8000_read_word(state, 597));
corm[1] = (dib8000_read_word(state, 598) << 16) | (dib8000_read_word(state, 599));
corm[0] = (dib8000_read_word(state, 600) << 16) | (dib8000_read_word(state, 601));
} else {
corm[2] = (dib8000_read_word(state, 594) << 16) | (dib8000_read_word(state, 595));
corm[1] = (dib8000_read_word(state, 596) << 16) | (dib8000_read_word(state, 597));
corm[0] = (dib8000_read_word(state, 598) << 16) | (dib8000_read_word(state, 599));
}
/* dprintk("corm fft: %u %u %u\n", corm[0], corm[1], corm[2]); */
max_value = 0;
for (find_index = 1 ; find_index < 3 ; find_index++) {
if (corm[max_value] < corm[find_index])
max_value = find_index ;
}
switch (max_value) {
case 0:
state->found_nfft = TRANSMISSION_MODE_2K;
break;
case 1:
state->found_nfft = TRANSMISSION_MODE_4K;
break;
case 2:
default:
state->found_nfft = TRANSMISSION_MODE_8K;
break;
}
/* dprintk("Autosearch FFT has found Mode %d\n", max_value + 1); */
*tune_state = CT_DEMOD_SEARCH_NEXT;
state->autosearch_state = AS_SEARCHING_GUARD;
if (state->revision == 0x8090)
ret = 50;
else
ret = 10;
break;
case AS_SEARCHING_GUARD:
/* searching for the correct guard interval */
if (state->revision == 0x8090)
state->found_guard = dib8000_read_word(state, 572) & 0x3;
else
state->found_guard = dib8000_read_word(state, 570) & 0x3;
/* dprintk("guard interval found=%i\n", state->found_guard); */
*tune_state = CT_DEMOD_STEP_3;
break;
default:
/* the demod should never be in this state */
state->status = FE_STATUS_TUNE_FAILED;
state->autosearch_state = AS_DONE;
*tune_state = CT_DEMOD_STOP; /* else we are done here */
break;
}
break;
case CT_DEMOD_STEP_3: /* 33 */
dib8000_set_isdbt_loop_params(state, LOOP_TUNE_1);
dib8000_set_isdbt_common_channel(state, 0, 0);/* setting the known channel parameters here */
*tune_state = CT_DEMOD_STEP_4;
break;
case CT_DEMOD_STEP_4: /* (34) */
dib8000_demod_restart(state);
dib8000_set_sync_wait(state);
dib8000_set_diversity_in(state->fe[0], state->diversity_onoff);
locks = (dib8000_read_word(state, 180) >> 6) & 0x3f; /* P_coff_winlen ? */
/* coff should lock over P_coff_winlen ofdm symbols : give 3 times this length to lock */
*timeout = dib8000_get_timeout(state, 2 * locks, SYMBOL_DEPENDENT_ON);
*tune_state = CT_DEMOD_STEP_5;
break;
case CT_DEMOD_STEP_5: /* (35) */
locks = dib8000_read_lock(fe);
if (locks & (0x3 << 11)) { /* coff-lock and off_cpil_lock achieved */
dib8000_update_timf(state); /* we achieved a coff_cpil_lock - it's time to update the timf */
if (!state->differential_constellation) {
/* 2 times lmod4_win_len + 10 symbols (pipe delay after coff + nb to compute a 1st correlation) */
*timeout = dib8000_get_timeout(state, (20 * ((dib8000_read_word(state, 188)>>5)&0x1f)), SYMBOL_DEPENDENT_ON);
*tune_state = CT_DEMOD_STEP_7;
} else {
*tune_state = CT_DEMOD_STEP_8;
}
} else if (time_after(now, *timeout)) {
*tune_state = CT_DEMOD_STEP_6; /* goto check for diversity input connection */
}
break;
case CT_DEMOD_STEP_6: /* (36) if there is an input (diversity) */
if ((state->fe[1] != NULL) && (state->output_mode != OUTMODE_DIVERSITY)) {
/* if there is a diversity fe in input and this fe is has not already failed : wait here until this this fe has succedeed or failed */
if (dib8000_get_status(state->fe[1]) <= FE_STATUS_STD_SUCCESS) /* Something is locked on the input fe */
*tune_state = CT_DEMOD_STEP_8; /* go for mpeg */
else if (dib8000_get_status(state->fe[1]) >= FE_STATUS_TUNE_TIME_TOO_SHORT) { /* fe in input failed also, break the current one */
*tune_state = CT_DEMOD_STOP; /* else we are done here ; step 8 will close the loops and exit */
dib8000_viterbi_state(state, 1); /* start viterbi chandec */
dib8000_set_isdbt_loop_params(state, LOOP_TUNE_2);
state->status = FE_STATUS_TUNE_FAILED;
}
} else {
dib8000_viterbi_state(state, 1); /* start viterbi chandec */
dib8000_set_isdbt_loop_params(state, LOOP_TUNE_2);
*tune_state = CT_DEMOD_STOP; /* else we are done here ; step 8 will close the loops and exit */
state->status = FE_STATUS_TUNE_FAILED;
}
break;
case CT_DEMOD_STEP_7: /* 37 */
locks = dib8000_read_lock(fe);
if (locks & (1<<10)) { /* lmod4_lock */
ret = 14; /* wait for 14 symbols */
*tune_state = CT_DEMOD_STEP_8;
} else if (time_after(now, *timeout))
*tune_state = CT_DEMOD_STEP_6; /* goto check for diversity input connection */
break;
case CT_DEMOD_STEP_8: /* 38 */
dib8000_viterbi_state(state, 1); /* start viterbi chandec */
dib8000_set_isdbt_loop_params(state, LOOP_TUNE_2);
/* mpeg will never lock on this condition because init_prbs is not set : search for it !*/
if (c->isdbt_sb_mode
&& c->isdbt_sb_subchannel < 14
&& !state->differential_constellation) {
state->subchannel = 0;
*tune_state = CT_DEMOD_STEP_11;
} else {
*tune_state = CT_DEMOD_STEP_9;
state->status = FE_STATUS_LOCKED;
}
break;
case CT_DEMOD_STEP_9: /* 39 */
if ((state->revision == 0x8090) || ((dib8000_read_word(state, 1291) >> 9) & 0x1)) { /* fe capable of deinterleaving : esram */
/* defines timeout for mpeg lock depending on interleaver length of longest layer */
for (i = 0; i < 3; i++) {
if (c->layer[i].interleaving >= deeper_interleaver) {
dprintk("layer%i: time interleaver = %d\n", i, c->layer[i].interleaving);
if (c->layer[i].segment_count > 0) { /* valid layer */
deeper_interleaver = c->layer[0].interleaving;
state->longest_intlv_layer = i;
}
}
}
if (deeper_interleaver == 0)
locks = 2; /* locks is the tmp local variable name */
else if (deeper_interleaver == 3)
locks = 8;
else
locks = 2 * deeper_interleaver;
if (state->diversity_onoff != 0) /* because of diversity sync */
locks *= 2;
*timeout = now + msecs_to_jiffies(200 * locks); /* give the mpeg lock 800ms if sram is present */
dprintk("Deeper interleaver mode = %d on layer %d : timeout mult factor = %d => will use timeout = %ld\n",
deeper_interleaver, state->longest_intlv_layer, locks, *timeout);
*tune_state = CT_DEMOD_STEP_10;
} else
*tune_state = CT_DEMOD_STOP;
break;
case CT_DEMOD_STEP_10: /* 40 */
locks = dib8000_read_lock(fe);
if (locks&(1<<(7-state->longest_intlv_layer))) { /* mpeg lock : check the longest one */
dprintk("ISDB-T layer locks: Layer A %s, Layer B %s, Layer C %s\n",
c->layer[0].segment_count ? (locks >> 7) & 0x1 ? "locked" : "NOT LOCKED" : "not enabled",
c->layer[1].segment_count ? (locks >> 6) & 0x1 ? "locked" : "NOT LOCKED" : "not enabled",
c->layer[2].segment_count ? (locks >> 5) & 0x1 ? "locked" : "NOT LOCKED" : "not enabled");
if (c->isdbt_sb_mode
&& c->isdbt_sb_subchannel < 14
&& !state->differential_constellation)
/* signal to the upper layer, that there was a channel found and the parameters can be read */
state->status = FE_STATUS_DEMOD_SUCCESS;
else
state->status = FE_STATUS_DATA_LOCKED;
*tune_state = CT_DEMOD_STOP;
} else if (time_after(now, *timeout)) {
if (c->isdbt_sb_mode
&& c->isdbt_sb_subchannel < 14
&& !state->differential_constellation) { /* continue to try init prbs autosearch */
state->subchannel += 3;
*tune_state = CT_DEMOD_STEP_11;
} else { /* we are done mpeg of the longest interleaver xas not locking but let's try if an other layer has locked in the same time */
if (locks & (0x7 << 5)) {
dprintk("Not all ISDB-T layers locked in %d ms: Layer A %s, Layer B %s, Layer C %s\n",
jiffies_to_msecs(now - *timeout),
c->layer[0].segment_count ? (locks >> 7) & 0x1 ? "locked" : "NOT LOCKED" : "not enabled",
c->layer[1].segment_count ? (locks >> 6) & 0x1 ? "locked" : "NOT LOCKED" : "not enabled",
c->layer[2].segment_count ? (locks >> 5) & 0x1 ? "locked" : "NOT LOCKED" : "not enabled");
state->status = FE_STATUS_DATA_LOCKED;
} else
state->status = FE_STATUS_TUNE_FAILED;
*tune_state = CT_DEMOD_STOP;
}
}
break;
case CT_DEMOD_STEP_11: /* 41 : init prbs autosearch */
if (state->subchannel <= 41) {
dib8000_set_subchannel_prbs(state, dib8000_get_init_prbs(state, state->subchannel));
*tune_state = CT_DEMOD_STEP_9;
} else {
*tune_state = CT_DEMOD_STOP;
state->status = FE_STATUS_TUNE_FAILED;
}
break;
default:
break;
}
/* tuning is finished - cleanup the demod */
switch (*tune_state) {
case CT_DEMOD_STOP: /* (42) */
#ifdef DIB8000_AGC_FREEZE
if ((state->revision != 0x8090) && (state->agc1_max != 0)) {
dib8000_write_word(state, 108, state->agc1_max);
dib8000_write_word(state, 109, state->agc1_min);
dib8000_write_word(state, 110, state->agc2_max);
dib8000_write_word(state, 111, state->agc2_min);
state->agc1_max = 0;
state->agc1_min = 0;
state->agc2_max = 0;
state->agc2_min = 0;
}
#endif
ret = 0;
break;
default:
break;
}
if ((ret > 0) && (*tune_state > CT_DEMOD_STEP_3))
return ret * state->symbol_duration;
if ((ret > 0) && (ret < state->symbol_duration))
return state->symbol_duration; /* at least one symbol */
return ret;
}
static int dib8000_wakeup(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
u8 index_frontend;
int ret;
dib8000_set_power_mode(state, DIB8000_POWER_ALL);
dib8000_set_adc_state(state, DIBX000_ADC_ON);
if (dib8000_set_adc_state(state, DIBX000_SLOW_ADC_ON) != 0)
dprintk("could not start Slow ADC\n");
if (state->revision == 0x8090)
dib8000_sad_calib(state);
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
ret = state->fe[index_frontend]->ops.init(state->fe[index_frontend]);
if (ret < 0)
return ret;
}
return 0;
}
static int dib8000_sleep(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
u8 index_frontend;
int ret;
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
ret = state->fe[index_frontend]->ops.sleep(state->fe[index_frontend]);
if (ret < 0)
return ret;
}
if (state->revision != 0x8090)
dib8000_set_output_mode(fe, OUTMODE_HIGH_Z);
dib8000_set_power_mode(state, DIB8000_POWER_INTERFACE_ONLY);
return dib8000_set_adc_state(state, DIBX000_SLOW_ADC_OFF) | dib8000_set_adc_state(state, DIBX000_ADC_OFF);
}
static int dib8000_read_status(struct dvb_frontend *fe, enum fe_status *stat);
static int dib8000_get_frontend(struct dvb_frontend *fe,
struct dtv_frontend_properties *c)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 i, val = 0;
enum fe_status stat = 0;
u8 index_frontend, sub_index_frontend;
c->bandwidth_hz = 6000000;
/*
* If called to early, get_frontend makes dib8000_tune to either
* not lock or not sync. This causes dvbv5-scan/dvbv5-zap to fail.
* So, let's just return if frontend 0 has not locked.
*/
dib8000_read_status(fe, &stat);
if (!(stat & FE_HAS_SYNC))
return 0;
dprintk("dib8000_get_frontend: TMCC lock\n");
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
state->fe[index_frontend]->ops.read_status(state->fe[index_frontend], &stat);
if (stat&FE_HAS_SYNC) {
dprintk("TMCC lock on the slave%i\n", index_frontend);
/* synchronize the cache with the other frontends */
state->fe[index_frontend]->ops.get_frontend(state->fe[index_frontend], c);
for (sub_index_frontend = 0; (sub_index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[sub_index_frontend] != NULL); sub_index_frontend++) {
if (sub_index_frontend != index_frontend) {
state->fe[sub_index_frontend]->dtv_property_cache.isdbt_sb_mode = state->fe[index_frontend]->dtv_property_cache.isdbt_sb_mode;
state->fe[sub_index_frontend]->dtv_property_cache.inversion = state->fe[index_frontend]->dtv_property_cache.inversion;
state->fe[sub_index_frontend]->dtv_property_cache.transmission_mode = state->fe[index_frontend]->dtv_property_cache.transmission_mode;
state->fe[sub_index_frontend]->dtv_property_cache.guard_interval = state->fe[index_frontend]->dtv_property_cache.guard_interval;
state->fe[sub_index_frontend]->dtv_property_cache.isdbt_partial_reception = state->fe[index_frontend]->dtv_property_cache.isdbt_partial_reception;
for (i = 0; i < 3; i++) {
state->fe[sub_index_frontend]->dtv_property_cache.layer[i].segment_count = state->fe[index_frontend]->dtv_property_cache.layer[i].segment_count;
state->fe[sub_index_frontend]->dtv_property_cache.layer[i].interleaving = state->fe[index_frontend]->dtv_property_cache.layer[i].interleaving;
state->fe[sub_index_frontend]->dtv_property_cache.layer[i].fec = state->fe[index_frontend]->dtv_property_cache.layer[i].fec;
state->fe[sub_index_frontend]->dtv_property_cache.layer[i].modulation = state->fe[index_frontend]->dtv_property_cache.layer[i].modulation;
}
}
}
return 0;
}
}
c->isdbt_sb_mode = dib8000_read_word(state, 508) & 0x1;
if (state->revision == 0x8090)
val = dib8000_read_word(state, 572);
else
val = dib8000_read_word(state, 570);
c->inversion = (val & 0x40) >> 6;
switch ((val & 0x30) >> 4) {
case 1:
c->transmission_mode = TRANSMISSION_MODE_2K;
dprintk("dib8000_get_frontend: transmission mode 2K\n");
break;
case 2:
c->transmission_mode = TRANSMISSION_MODE_4K;
dprintk("dib8000_get_frontend: transmission mode 4K\n");
break;
case 3:
default:
c->transmission_mode = TRANSMISSION_MODE_8K;
dprintk("dib8000_get_frontend: transmission mode 8K\n");
break;
}
switch (val & 0x3) {
case 0:
c->guard_interval = GUARD_INTERVAL_1_32;
dprintk("dib8000_get_frontend: Guard Interval = 1/32\n");
break;
case 1:
c->guard_interval = GUARD_INTERVAL_1_16;
dprintk("dib8000_get_frontend: Guard Interval = 1/16\n");
break;
case 2:
dprintk("dib8000_get_frontend: Guard Interval = 1/8\n");
c->guard_interval = GUARD_INTERVAL_1_8;
break;
case 3:
dprintk("dib8000_get_frontend: Guard Interval = 1/4\n");
c->guard_interval = GUARD_INTERVAL_1_4;
break;
}
val = dib8000_read_word(state, 505);
c->isdbt_partial_reception = val & 1;
dprintk("dib8000_get_frontend: partial_reception = %d\n", c->isdbt_partial_reception);
for (i = 0; i < 3; i++) {
int show;
val = dib8000_read_word(state, 493 + i) & 0x0f;
c->layer[i].segment_count = val;
if (val == 0 || val > 13)
show = 0;
else
show = 1;
if (show)
dprintk("dib8000_get_frontend: Layer %d segments = %d\n",
i, c->layer[i].segment_count);
val = dib8000_read_word(state, 499 + i) & 0x3;
/* Interleaving can be 0, 1, 2 or 4 */
if (val == 3)
val = 4;
c->layer[i].interleaving = val;
if (show)
dprintk("dib8000_get_frontend: Layer %d time_intlv = %d\n",
i, c->layer[i].interleaving);
val = dib8000_read_word(state, 481 + i);
switch (val & 0x7) {
case 1:
c->layer[i].fec = FEC_1_2;
if (show)
dprintk("dib8000_get_frontend: Layer %d Code Rate = 1/2\n", i);
break;
case 2:
c->layer[i].fec = FEC_2_3;
if (show)
dprintk("dib8000_get_frontend: Layer %d Code Rate = 2/3\n", i);
break;
case 3:
c->layer[i].fec = FEC_3_4;
if (show)
dprintk("dib8000_get_frontend: Layer %d Code Rate = 3/4\n", i);
break;
case 5:
c->layer[i].fec = FEC_5_6;
if (show)
dprintk("dib8000_get_frontend: Layer %d Code Rate = 5/6\n", i);
break;
default:
c->layer[i].fec = FEC_7_8;
if (show)
dprintk("dib8000_get_frontend: Layer %d Code Rate = 7/8\n", i);
break;
}
val = dib8000_read_word(state, 487 + i);
switch (val & 0x3) {
case 0:
c->layer[i].modulation = DQPSK;
if (show)
dprintk("dib8000_get_frontend: Layer %d DQPSK\n", i);
break;
case 1:
c->layer[i].modulation = QPSK;
if (show)
dprintk("dib8000_get_frontend: Layer %d QPSK\n", i);
break;
case 2:
c->layer[i].modulation = QAM_16;
if (show)
dprintk("dib8000_get_frontend: Layer %d QAM16\n", i);
break;
case 3:
default:
c->layer[i].modulation = QAM_64;
if (show)
dprintk("dib8000_get_frontend: Layer %d QAM64\n", i);
break;
}
}
/* synchronize the cache with the other frontends */
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
state->fe[index_frontend]->dtv_property_cache.isdbt_sb_mode = c->isdbt_sb_mode;
state->fe[index_frontend]->dtv_property_cache.inversion = c->inversion;
state->fe[index_frontend]->dtv_property_cache.transmission_mode = c->transmission_mode;
state->fe[index_frontend]->dtv_property_cache.guard_interval = c->guard_interval;
state->fe[index_frontend]->dtv_property_cache.isdbt_partial_reception = c->isdbt_partial_reception;
for (i = 0; i < 3; i++) {
state->fe[index_frontend]->dtv_property_cache.layer[i].segment_count = c->layer[i].segment_count;
state->fe[index_frontend]->dtv_property_cache.layer[i].interleaving = c->layer[i].interleaving;
state->fe[index_frontend]->dtv_property_cache.layer[i].fec = c->layer[i].fec;
state->fe[index_frontend]->dtv_property_cache.layer[i].modulation = c->layer[i].modulation;
}
}
return 0;
}
static int dib8000_set_frontend(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
int l, i, active, time, time_slave = 0;
u8 exit_condition, index_frontend;
unsigned long delay, callback_time;
if (c->frequency == 0) {
dprintk("dib8000: must at least specify frequency\n");
return 0;
}
if (c->bandwidth_hz == 0) {
dprintk("dib8000: no bandwidth specified, set to default\n");
c->bandwidth_hz = 6000000;
}
for (index_frontend = 0; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
/* synchronization of the cache */
state->fe[index_frontend]->dtv_property_cache.delivery_system = SYS_ISDBT;
memcpy(&state->fe[index_frontend]->dtv_property_cache, &fe->dtv_property_cache, sizeof(struct dtv_frontend_properties));
/* set output mode and diversity input */
if (state->revision != 0x8090) {
dib8000_set_diversity_in(state->fe[index_frontend], 1);
if (index_frontend != 0)
dib8000_set_output_mode(state->fe[index_frontend],
OUTMODE_DIVERSITY);
else
dib8000_set_output_mode(state->fe[0], OUTMODE_HIGH_Z);
} else {
dib8096p_set_diversity_in(state->fe[index_frontend], 1);
if (index_frontend != 0)
dib8096p_set_output_mode(state->fe[index_frontend],
OUTMODE_DIVERSITY);
else
dib8096p_set_output_mode(state->fe[0], OUTMODE_HIGH_Z);
}
/* tune the tuner */
if (state->fe[index_frontend]->ops.tuner_ops.set_params)
state->fe[index_frontend]->ops.tuner_ops.set_params(state->fe[index_frontend]);
dib8000_set_tune_state(state->fe[index_frontend], CT_AGC_START);
}
/* turn off the diversity of the last chip */
if (state->revision != 0x8090)
dib8000_set_diversity_in(state->fe[index_frontend - 1], 0);
else
dib8096p_set_diversity_in(state->fe[index_frontend - 1], 0);
/* start up the AGC */
do {
time = dib8000_agc_startup(state->fe[0]);
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
time_slave = dib8000_agc_startup(state->fe[index_frontend]);
if (time == 0)
time = time_slave;
else if ((time_slave != 0) && (time_slave > time))
time = time_slave;
}
if (time == 0)
break;
/*
* Despite dib8000_agc_startup returns time at a 0.1 ms range,
* the actual sleep time depends on CONFIG_HZ. The worse case
* is when CONFIG_HZ=100. In such case, the minimum granularity
* is 10ms. On some real field tests, the tuner sometimes don't
* lock when this timer is lower than 10ms. So, enforce a 10ms
* granularity.
*/
time = 10 * (time + 99)/100;
usleep_range(time * 1000, (time + 1) * 1000);
exit_condition = 1;
for (index_frontend = 0; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
if (dib8000_get_tune_state(state->fe[index_frontend]) != CT_AGC_STOP) {
exit_condition = 0;
break;
}
}
} while (exit_condition == 0);
for (index_frontend = 0; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++)
dib8000_set_tune_state(state->fe[index_frontend], CT_DEMOD_START);
active = 1;
do {
callback_time = 0;
for (index_frontend = 0; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
delay = dib8000_tune(state->fe[index_frontend]);
if (delay != 0) {
delay = jiffies + usecs_to_jiffies(100 * delay);
if (!callback_time || delay < callback_time)
callback_time = delay;
}
/* we are in autosearch */
if (state->channel_parameters_set == 0) { /* searching */
if ((dib8000_get_status(state->fe[index_frontend]) == FE_STATUS_DEMOD_SUCCESS) || (dib8000_get_status(state->fe[index_frontend]) == FE_STATUS_FFT_SUCCESS)) {
dprintk("autosearch succeeded on fe%i\n", index_frontend);
dib8000_get_frontend(state->fe[index_frontend], c); /* we read the channel parameters from the frontend which was successful */
state->channel_parameters_set = 1;
for (l = 0; (l < MAX_NUMBER_OF_FRONTENDS) && (state->fe[l] != NULL); l++) {
if (l != index_frontend) { /* and for all frontend except the successful one */
dprintk("Restarting frontend %d\n", l);
dib8000_tune_restart_from_demod(state->fe[l]);
state->fe[l]->dtv_property_cache.isdbt_sb_mode = state->fe[index_frontend]->dtv_property_cache.isdbt_sb_mode;
state->fe[l]->dtv_property_cache.inversion = state->fe[index_frontend]->dtv_property_cache.inversion;
state->fe[l]->dtv_property_cache.transmission_mode = state->fe[index_frontend]->dtv_property_cache.transmission_mode;
state->fe[l]->dtv_property_cache.guard_interval = state->fe[index_frontend]->dtv_property_cache.guard_interval;
state->fe[l]->dtv_property_cache.isdbt_partial_reception = state->fe[index_frontend]->dtv_property_cache.isdbt_partial_reception;
for (i = 0; i < 3; i++) {
state->fe[l]->dtv_property_cache.layer[i].segment_count = state->fe[index_frontend]->dtv_property_cache.layer[i].segment_count;
state->fe[l]->dtv_property_cache.layer[i].interleaving = state->fe[index_frontend]->dtv_property_cache.layer[i].interleaving;
state->fe[l]->dtv_property_cache.layer[i].fec = state->fe[index_frontend]->dtv_property_cache.layer[i].fec;
state->fe[l]->dtv_property_cache.layer[i].modulation = state->fe[index_frontend]->dtv_property_cache.layer[i].modulation;
}
}
}
}
}
}
/* tuning is done when the master frontend is done (failed or success) */
if (dib8000_get_status(state->fe[0]) == FE_STATUS_TUNE_FAILED ||
dib8000_get_status(state->fe[0]) == FE_STATUS_LOCKED ||
dib8000_get_status(state->fe[0]) == FE_STATUS_DATA_LOCKED) {
active = 0;
/* we need to wait for all frontends to be finished */
for (index_frontend = 0; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
if (dib8000_get_tune_state(state->fe[index_frontend]) != CT_DEMOD_STOP)
active = 1;
}
if (active == 0)
dprintk("tuning done with status %d\n", dib8000_get_status(state->fe[0]));
}
if ((active == 1) && (callback_time == 0)) {
dprintk("strange callback time something went wrong\n");
active = 0;
}
while ((active == 1) && (time_before(jiffies, callback_time)))
msleep(100);
} while (active);
/* set output mode */
if (state->revision != 0x8090)
dib8000_set_output_mode(state->fe[0], state->cfg.output_mode);
else {
dib8096p_set_output_mode(state->fe[0], state->cfg.output_mode);
if (state->cfg.enMpegOutput == 0) {
dib8096p_setDibTxMux(state, MPEG_ON_DIBTX);
dib8096p_setHostBusMux(state, DIBTX_ON_HOSTBUS);
}
}
return 0;
}
static int dib8000_get_stats(struct dvb_frontend *fe, enum fe_status stat);
static int dib8000_read_status(struct dvb_frontend *fe, enum fe_status *stat)
{
struct dib8000_state *state = fe->demodulator_priv;
u16 lock_slave = 0, lock;
u8 index_frontend;
lock = dib8000_read_lock(fe);
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++)
lock_slave |= dib8000_read_lock(state->fe[index_frontend]);
*stat = 0;
if (((lock >> 13) & 1) || ((lock_slave >> 13) & 1))
*stat |= FE_HAS_SIGNAL;
if (((lock >> 8) & 1) || ((lock_slave >> 8) & 1)) /* Equal */
*stat |= FE_HAS_CARRIER;
if ((((lock >> 1) & 0xf) == 0xf) || (((lock_slave >> 1) & 0xf) == 0xf)) /* TMCC_SYNC */
*stat |= FE_HAS_SYNC;
if ((((lock >> 12) & 1) || ((lock_slave >> 12) & 1)) && ((lock >> 5) & 7)) /* FEC MPEG */
*stat |= FE_HAS_LOCK;
if (((lock >> 12) & 1) || ((lock_slave >> 12) & 1)) {
lock = dib8000_read_word(state, 554); /* Viterbi Layer A */
if (lock & 0x01)
*stat |= FE_HAS_VITERBI;
lock = dib8000_read_word(state, 555); /* Viterbi Layer B */
if (lock & 0x01)
*stat |= FE_HAS_VITERBI;
lock = dib8000_read_word(state, 556); /* Viterbi Layer C */
if (lock & 0x01)
*stat |= FE_HAS_VITERBI;
}
dib8000_get_stats(fe, *stat);
return 0;
}
static int dib8000_read_ber(struct dvb_frontend *fe, u32 * ber)
{
struct dib8000_state *state = fe->demodulator_priv;
/* 13 segments */
if (state->revision == 0x8090)
*ber = (dib8000_read_word(state, 562) << 16) |
dib8000_read_word(state, 563);
else
*ber = (dib8000_read_word(state, 560) << 16) |
dib8000_read_word(state, 561);
return 0;
}
static int dib8000_read_unc_blocks(struct dvb_frontend *fe, u32 * unc)
{
struct dib8000_state *state = fe->demodulator_priv;
/* packet error on 13 seg */
if (state->revision == 0x8090)
*unc = dib8000_read_word(state, 567);
else
*unc = dib8000_read_word(state, 565);
return 0;
}
static int dib8000_read_signal_strength(struct dvb_frontend *fe, u16 * strength)
{
struct dib8000_state *state = fe->demodulator_priv;
u8 index_frontend;
u16 val;
*strength = 0;
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++) {
state->fe[index_frontend]->ops.read_signal_strength(state->fe[index_frontend], &val);
if (val > 65535 - *strength)
*strength = 65535;
else
*strength += val;
}
val = 65535 - dib8000_read_word(state, 390);
if (val > 65535 - *strength)
*strength = 65535;
else
*strength += val;
return 0;
}
static u32 dib8000_get_snr(struct dvb_frontend *fe)
{
struct dib8000_state *state = fe->demodulator_priv;
u32 n, s, exp;
u16 val;
if (state->revision != 0x8090)
val = dib8000_read_word(state, 542);
else
val = dib8000_read_word(state, 544);
n = (val >> 6) & 0xff;
exp = (val & 0x3f);
if ((exp & 0x20) != 0)
exp -= 0x40;
n <<= exp+16;
if (state->revision != 0x8090)
val = dib8000_read_word(state, 543);
else
val = dib8000_read_word(state, 545);
s = (val >> 6) & 0xff;
exp = (val & 0x3f);
if ((exp & 0x20) != 0)
exp -= 0x40;
s <<= exp+16;
if (n > 0) {
u32 t = (s/n) << 16;
return t + ((s << 16) - n*t) / n;
}
return 0xffffffff;
}
static int dib8000_read_snr(struct dvb_frontend *fe, u16 * snr)
{
struct dib8000_state *state = fe->demodulator_priv;
u8 index_frontend;
u32 snr_master;
snr_master = dib8000_get_snr(fe);
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL); index_frontend++)
snr_master += dib8000_get_snr(state->fe[index_frontend]);
if ((snr_master >> 16) != 0) {
snr_master = 10*intlog10(snr_master>>16);
*snr = snr_master / ((1 << 24) / 10);
}
else
*snr = 0;
return 0;
}
struct per_layer_regs {
u16 lock, ber, per;
};
static const struct per_layer_regs per_layer_regs[] = {
{ 554, 560, 562 },
{ 555, 576, 578 },
{ 556, 581, 583 },
};
struct linear_segments {
unsigned x;
signed y;
};
/*
* Table to estimate signal strength in dBm.
* This table was empirically determinated by measuring the signal
* strength generated by a DTA-2111 RF generator directly connected into
* a dib8076 device (a PixelView PV-D231U stick), using a good quality
* 3 meters RC6 cable and good RC6 connectors.
* The real value can actually be different on other devices, depending
* on several factors, like if LNA is enabled or not, if diversity is
* enabled, type of connectors, etc.
* Yet, it is better to use this measure in dB than a random non-linear
* percentage value, especially for antenna adjustments.
* On my tests, the precision of the measure using this table is about
* 0.5 dB, with sounds reasonable enough.
*/
static struct linear_segments strength_to_db_table[] = {
{ 55953, 108500 }, /* -22.5 dBm */
{ 55394, 108000 },
{ 53834, 107000 },
{ 52863, 106000 },
{ 52239, 105000 },
{ 52012, 104000 },
{ 51803, 103000 },
{ 51566, 102000 },
{ 51356, 101000 },
{ 51112, 100000 },
{ 50869, 99000 },
{ 50600, 98000 },
{ 50363, 97000 },
{ 50117, 96000 }, /* -35 dBm */
{ 49889, 95000 },
{ 49680, 94000 },
{ 49493, 93000 },
{ 49302, 92000 },
{ 48929, 91000 },
{ 48416, 90000 },
{ 48035, 89000 },
{ 47593, 88000 },
{ 47282, 87000 },
{ 46953, 86000 },
{ 46698, 85000 },
{ 45617, 84000 },
{ 44773, 83000 },
{ 43845, 82000 },
{ 43020, 81000 },
{ 42010, 80000 }, /* -51 dBm */
{ 0, 0 },
};
static u32 interpolate_value(u32 value, struct linear_segments *segments,
unsigned len)
{
u64 tmp64;
u32 dx;
s32 dy;
int i, ret;
if (value >= segments[0].x)
return segments[0].y;
if (value < segments[len-1].x)
return segments[len-1].y;
for (i = 1; i < len - 1; i++) {
/* If value is identical, no need to interpolate */
if (value == segments[i].x)
return segments[i].y;
if (value > segments[i].x)
break;
}
/* Linear interpolation between the two (x,y) points */
dy = segments[i - 1].y - segments[i].y;
dx = segments[i - 1].x - segments[i].x;
tmp64 = value - segments[i].x;
tmp64 *= dy;
do_div(tmp64, dx);
ret = segments[i].y + tmp64;
return ret;
}
static u32 dib8000_get_time_us(struct dvb_frontend *fe, int layer)
{
struct dib8000_state *state = fe->demodulator_priv;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
int ini_layer, end_layer, i;
u64 time_us, tmp64;
u32 tmp, denom;
int guard, rate_num, rate_denum = 1, bits_per_symbol, nsegs;
int interleaving = 0, fft_div;
if (layer >= 0) {
ini_layer = layer;
end_layer = layer + 1;
} else {
ini_layer = 0;
end_layer = 3;
}
switch (c->guard_interval) {
case GUARD_INTERVAL_1_4:
guard = 4;
break;
case GUARD_INTERVAL_1_8:
guard = 8;
break;
case GUARD_INTERVAL_1_16:
guard = 16;
break;
default:
case GUARD_INTERVAL_1_32:
guard = 32;
break;
}
switch (c->transmission_mode) {
case TRANSMISSION_MODE_2K:
fft_div = 4;
break;
case TRANSMISSION_MODE_4K:
fft_div = 2;
break;
default:
case TRANSMISSION_MODE_8K:
fft_div = 1;
break;
}
denom = 0;
for (i = ini_layer; i < end_layer; i++) {
nsegs = c->layer[i].segment_count;
if (nsegs == 0 || nsegs > 13)
continue;
switch (c->layer[i].modulation) {
case DQPSK:
case QPSK:
bits_per_symbol = 2;
break;
case QAM_16:
bits_per_symbol = 4;
break;
default:
case QAM_64:
bits_per_symbol = 6;
break;
}
switch (c->layer[i].fec) {
case FEC_1_2:
rate_num = 1;
rate_denum = 2;
break;
case FEC_2_3:
rate_num = 2;
rate_denum = 3;
break;
case FEC_3_4:
rate_num = 3;
rate_denum = 4;
break;
case FEC_5_6:
rate_num = 5;
rate_denum = 6;
break;
default:
case FEC_7_8:
rate_num = 7;
rate_denum = 8;
break;
}
interleaving = c->layer[i].interleaving;
denom += bits_per_symbol * rate_num * fft_div * nsegs * 384;
}
/* If all goes wrong, wait for 1s for the next stats */
if (!denom)
return 0;
/* Estimate the period for the total bit rate */
time_us = rate_denum * (1008 * 1562500L);
tmp64 = time_us;
do_div(tmp64, guard);
time_us = time_us + tmp64;
time_us += denom / 2;
do_div(time_us, denom);
tmp = 1008 * 96 * interleaving;
time_us += tmp + tmp / guard;
return time_us;
}
static int dib8000_get_stats(struct dvb_frontend *fe, enum fe_status stat)
{
struct dib8000_state *state = fe->demodulator_priv;
struct dtv_frontend_properties *c = &state->fe[0]->dtv_property_cache;
int i;
int show_per_stats = 0;
u32 time_us = 0, snr, val;
u64 blocks;
s32 db;
u16 strength;
/* Get Signal strength */
dib8000_read_signal_strength(fe, &strength);
val = strength;
db = interpolate_value(val,
strength_to_db_table,
ARRAY_SIZE(strength_to_db_table)) - 131000;
c->strength.stat[0].svalue = db;
/* UCB/BER/CNR measures require lock */
if (!(stat & FE_HAS_LOCK)) {
c->cnr.len = 1;
c->block_count.len = 1;
c->block_error.len = 1;
c->post_bit_error.len = 1;
c->post_bit_count.len = 1;
c->cnr.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->post_bit_error.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->post_bit_count.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->block_error.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
c->block_count.stat[0].scale = FE_SCALE_NOT_AVAILABLE;
return 0;
}
/* Check if time for stats was elapsed */
if (time_after(jiffies, state->per_jiffies_stats)) {
state->per_jiffies_stats = jiffies + msecs_to_jiffies(1000);
/* Get SNR */
snr = dib8000_get_snr(fe);
for (i = 1; i < MAX_NUMBER_OF_FRONTENDS; i++) {
if (state->fe[i])
snr += dib8000_get_snr(state->fe[i]);
}
snr = snr >> 16;
if (snr) {
snr = 10 * intlog10(snr);
snr = (1000L * snr) >> 24;
} else {
snr = 0;
}
c->cnr.stat[0].svalue = snr;
c->cnr.stat[0].scale = FE_SCALE_DECIBEL;
/* Get UCB measures */
dib8000_read_unc_blocks(fe, &val);
if (val < state->init_ucb)
state->init_ucb += 0x100000000LL;
c->block_error.stat[0].scale = FE_SCALE_COUNTER;
c->block_error.stat[0].uvalue = val + state->init_ucb;
/* Estimate the number of packets based on bitrate */
if (!time_us)
time_us = dib8000_get_time_us(fe, -1);
if (time_us) {
blocks = 1250000ULL * 1000000ULL;
do_div(blocks, time_us * 8 * 204);
c->block_count.stat[0].scale = FE_SCALE_COUNTER;
c->block_count.stat[0].uvalue += blocks;
}
show_per_stats = 1;
}
/* Get post-BER measures */
if (time_after(jiffies, state->ber_jiffies_stats)) {
time_us = dib8000_get_time_us(fe, -1);
state->ber_jiffies_stats = jiffies + msecs_to_jiffies((time_us + 500) / 1000);
dprintk("Next all layers stats available in %u us.\n", time_us);
dib8000_read_ber(fe, &val);
c->post_bit_error.stat[0].scale = FE_SCALE_COUNTER;
c->post_bit_error.stat[0].uvalue += val;
c->post_bit_count.stat[0].scale = FE_SCALE_COUNTER;
c->post_bit_count.stat[0].uvalue += 100000000;
}
if (state->revision < 0x8002)
return 0;
c->block_error.len = 4;
c->post_bit_error.len = 4;
c->post_bit_count.len = 4;
for (i = 0; i < 3; i++) {
unsigned nsegs = c->layer[i].segment_count;
if (nsegs == 0 || nsegs > 13)
continue;
time_us = 0;
if (time_after(jiffies, state->ber_jiffies_stats_layer[i])) {
time_us = dib8000_get_time_us(fe, i);
state->ber_jiffies_stats_layer[i] = jiffies + msecs_to_jiffies((time_us + 500) / 1000);
dprintk("Next layer %c stats will be available in %u us\n",
'A' + i, time_us);
val = dib8000_read_word(state, per_layer_regs[i].ber);
c->post_bit_error.stat[1 + i].scale = FE_SCALE_COUNTER;
c->post_bit_error.stat[1 + i].uvalue += val;
c->post_bit_count.stat[1 + i].scale = FE_SCALE_COUNTER;
c->post_bit_count.stat[1 + i].uvalue += 100000000;
}
if (show_per_stats) {
val = dib8000_read_word(state, per_layer_regs[i].per);
c->block_error.stat[1 + i].scale = FE_SCALE_COUNTER;
c->block_error.stat[1 + i].uvalue += val;
if (!time_us)
time_us = dib8000_get_time_us(fe, i);
if (time_us) {
blocks = 1250000ULL * 1000000ULL;
do_div(blocks, time_us * 8 * 204);
c->block_count.stat[0].scale = FE_SCALE_COUNTER;
c->block_count.stat[0].uvalue += blocks;
}
}
}
return 0;
}
static int dib8000_set_slave_frontend(struct dvb_frontend *fe, struct dvb_frontend *fe_slave)
{
struct dib8000_state *state = fe->demodulator_priv;
u8 index_frontend = 1;
while ((index_frontend < MAX_NUMBER_OF_FRONTENDS) && (state->fe[index_frontend] != NULL))
index_frontend++;
if (index_frontend < MAX_NUMBER_OF_FRONTENDS) {
dprintk("set slave fe %p to index %i\n", fe_slave, index_frontend);
state->fe[index_frontend] = fe_slave;
return 0;
}
dprintk("too many slave frontend\n");
return -ENOMEM;
}
static struct dvb_frontend *dib8000_get_slave_frontend(struct dvb_frontend *fe, int slave_index)
{
struct dib8000_state *state = fe->demodulator_priv;
if (slave_index >= MAX_NUMBER_OF_FRONTENDS)
return NULL;
return state->fe[slave_index];
}
static int dib8000_i2c_enumeration(struct i2c_adapter *host, int no_of_demods,
u8 default_addr, u8 first_addr, u8 is_dib8096p)
{
int k = 0, ret = 0;
u8 new_addr = 0;
struct i2c_device client = {.adap = host };
treewide: kzalloc() -> kcalloc() The kzalloc() function has a 2-factor argument form, kcalloc(). This patch replaces cases of: kzalloc(a * b, gfp) with: kcalloc(a * b, gfp) as well as handling cases of: kzalloc(a * b * c, gfp) with: kzalloc(array3_size(a, b, c), gfp) as it's slightly less ugly than: kzalloc_array(array_size(a, b), c, gfp) This does, however, attempt to ignore constant size factors like: kzalloc(4 * 1024, gfp) though any constants defined via macros get caught up in the conversion. Any factors with a sizeof() of "unsigned char", "char", and "u8" were dropped, since they're redundant. The Coccinelle script used for this was: // Fix redundant parens around sizeof(). @@ type TYPE; expression THING, E; @@ ( kzalloc( - (sizeof(TYPE)) * E + sizeof(TYPE) * E , ...) | kzalloc( - (sizeof(THING)) * E + sizeof(THING) * E , ...) ) // Drop single-byte sizes and redundant parens. @@ expression COUNT; typedef u8; typedef __u8; @@ ( kzalloc( - sizeof(u8) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(__u8) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(char) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(unsigned char) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(u8) * COUNT + COUNT , ...) | kzalloc( - sizeof(__u8) * COUNT + COUNT , ...) | kzalloc( - sizeof(char) * COUNT + COUNT , ...) | kzalloc( - sizeof(unsigned char) * COUNT + COUNT , ...) ) // 2-factor product with sizeof(type/expression) and identifier or constant. @@ type TYPE; expression THING; identifier COUNT_ID; constant COUNT_CONST; @@ ( - kzalloc + kcalloc ( - sizeof(TYPE) * (COUNT_ID) + COUNT_ID, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * COUNT_ID + COUNT_ID, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * (COUNT_CONST) + COUNT_CONST, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * COUNT_CONST + COUNT_CONST, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (COUNT_ID) + COUNT_ID, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * COUNT_ID + COUNT_ID, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (COUNT_CONST) + COUNT_CONST, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * COUNT_CONST + COUNT_CONST, sizeof(THING) , ...) ) // 2-factor product, only identifiers. @@ identifier SIZE, COUNT; @@ - kzalloc + kcalloc ( - SIZE * COUNT + COUNT, SIZE , ...) // 3-factor product with 1 sizeof(type) or sizeof(expression), with // redundant parens removed. @@ expression THING; identifier STRIDE, COUNT; type TYPE; @@ ( kzalloc( - sizeof(TYPE) * (COUNT) * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * (COUNT) * STRIDE + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * COUNT * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * COUNT * STRIDE + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(THING) * (COUNT) * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * (COUNT) * STRIDE + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * COUNT * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * COUNT * STRIDE + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) ) // 3-factor product with 2 sizeof(variable), with redundant parens removed. @@ expression THING1, THING2; identifier COUNT; type TYPE1, TYPE2; @@ ( kzalloc( - sizeof(TYPE1) * sizeof(TYPE2) * COUNT + array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2)) , ...) | kzalloc( - sizeof(THING1) * sizeof(THING2) * COUNT + array3_size(COUNT, sizeof(THING1), sizeof(THING2)) , ...) | kzalloc( - sizeof(THING1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(THING1), sizeof(THING2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * COUNT + array3_size(COUNT, sizeof(TYPE1), sizeof(THING2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(TYPE1), sizeof(THING2)) , ...) ) // 3-factor product, only identifiers, with redundant parens removed. @@ identifier STRIDE, SIZE, COUNT; @@ ( kzalloc( - (COUNT) * STRIDE * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * (STRIDE) * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * STRIDE * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * (STRIDE) * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * (STRIDE) * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * STRIDE * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * (STRIDE) * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * STRIDE * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) ) // Any remaining multi-factor products, first at least 3-factor products, // when they're not all constants... @@ expression E1, E2, E3; constant C1, C2, C3; @@ ( kzalloc(C1 * C2 * C3, ...) | kzalloc( - (E1) * E2 * E3 + array3_size(E1, E2, E3) , ...) | kzalloc( - (E1) * (E2) * E3 + array3_size(E1, E2, E3) , ...) | kzalloc( - (E1) * (E2) * (E3) + array3_size(E1, E2, E3) , ...) | kzalloc( - E1 * E2 * E3 + array3_size(E1, E2, E3) , ...) ) // And then all remaining 2 factors products when they're not all constants, // keeping sizeof() as the second factor argument. @@ expression THING, E1, E2; type TYPE; constant C1, C2, C3; @@ ( kzalloc(sizeof(THING) * C2, ...) | kzalloc(sizeof(TYPE) * C2, ...) | kzalloc(C1 * C2 * C3, ...) | kzalloc(C1 * C2, ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * (E2) + E2, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * E2 + E2, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (E2) + E2, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * E2 + E2, sizeof(THING) , ...) | - kzalloc + kcalloc ( - (E1) * E2 + E1, E2 , ...) | - kzalloc + kcalloc ( - (E1) * (E2) + E1, E2 , ...) | - kzalloc + kcalloc ( - E1 * E2 + E1, E2 , ...) ) Signed-off-by: Kees Cook <keescook@chromium.org>
2018-06-13 00:03:40 +03:00
client.i2c_write_buffer = kzalloc(4, GFP_KERNEL);
if (!client.i2c_write_buffer) {
dprintk("%s: not enough memory\n", __func__);
return -ENOMEM;
}
treewide: kzalloc() -> kcalloc() The kzalloc() function has a 2-factor argument form, kcalloc(). This patch replaces cases of: kzalloc(a * b, gfp) with: kcalloc(a * b, gfp) as well as handling cases of: kzalloc(a * b * c, gfp) with: kzalloc(array3_size(a, b, c), gfp) as it's slightly less ugly than: kzalloc_array(array_size(a, b), c, gfp) This does, however, attempt to ignore constant size factors like: kzalloc(4 * 1024, gfp) though any constants defined via macros get caught up in the conversion. Any factors with a sizeof() of "unsigned char", "char", and "u8" were dropped, since they're redundant. The Coccinelle script used for this was: // Fix redundant parens around sizeof(). @@ type TYPE; expression THING, E; @@ ( kzalloc( - (sizeof(TYPE)) * E + sizeof(TYPE) * E , ...) | kzalloc( - (sizeof(THING)) * E + sizeof(THING) * E , ...) ) // Drop single-byte sizes and redundant parens. @@ expression COUNT; typedef u8; typedef __u8; @@ ( kzalloc( - sizeof(u8) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(__u8) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(char) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(unsigned char) * (COUNT) + COUNT , ...) | kzalloc( - sizeof(u8) * COUNT + COUNT , ...) | kzalloc( - sizeof(__u8) * COUNT + COUNT , ...) | kzalloc( - sizeof(char) * COUNT + COUNT , ...) | kzalloc( - sizeof(unsigned char) * COUNT + COUNT , ...) ) // 2-factor product with sizeof(type/expression) and identifier or constant. @@ type TYPE; expression THING; identifier COUNT_ID; constant COUNT_CONST; @@ ( - kzalloc + kcalloc ( - sizeof(TYPE) * (COUNT_ID) + COUNT_ID, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * COUNT_ID + COUNT_ID, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * (COUNT_CONST) + COUNT_CONST, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * COUNT_CONST + COUNT_CONST, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (COUNT_ID) + COUNT_ID, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * COUNT_ID + COUNT_ID, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (COUNT_CONST) + COUNT_CONST, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * COUNT_CONST + COUNT_CONST, sizeof(THING) , ...) ) // 2-factor product, only identifiers. @@ identifier SIZE, COUNT; @@ - kzalloc + kcalloc ( - SIZE * COUNT + COUNT, SIZE , ...) // 3-factor product with 1 sizeof(type) or sizeof(expression), with // redundant parens removed. @@ expression THING; identifier STRIDE, COUNT; type TYPE; @@ ( kzalloc( - sizeof(TYPE) * (COUNT) * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * (COUNT) * STRIDE + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * COUNT * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(TYPE) * COUNT * STRIDE + array3_size(COUNT, STRIDE, sizeof(TYPE)) , ...) | kzalloc( - sizeof(THING) * (COUNT) * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * (COUNT) * STRIDE + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * COUNT * (STRIDE) + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) | kzalloc( - sizeof(THING) * COUNT * STRIDE + array3_size(COUNT, STRIDE, sizeof(THING)) , ...) ) // 3-factor product with 2 sizeof(variable), with redundant parens removed. @@ expression THING1, THING2; identifier COUNT; type TYPE1, TYPE2; @@ ( kzalloc( - sizeof(TYPE1) * sizeof(TYPE2) * COUNT + array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(TYPE1), sizeof(TYPE2)) , ...) | kzalloc( - sizeof(THING1) * sizeof(THING2) * COUNT + array3_size(COUNT, sizeof(THING1), sizeof(THING2)) , ...) | kzalloc( - sizeof(THING1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(THING1), sizeof(THING2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * COUNT + array3_size(COUNT, sizeof(TYPE1), sizeof(THING2)) , ...) | kzalloc( - sizeof(TYPE1) * sizeof(THING2) * (COUNT) + array3_size(COUNT, sizeof(TYPE1), sizeof(THING2)) , ...) ) // 3-factor product, only identifiers, with redundant parens removed. @@ identifier STRIDE, SIZE, COUNT; @@ ( kzalloc( - (COUNT) * STRIDE * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * (STRIDE) * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * STRIDE * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * (STRIDE) * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * (STRIDE) * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * STRIDE * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - (COUNT) * (STRIDE) * (SIZE) + array3_size(COUNT, STRIDE, SIZE) , ...) | kzalloc( - COUNT * STRIDE * SIZE + array3_size(COUNT, STRIDE, SIZE) , ...) ) // Any remaining multi-factor products, first at least 3-factor products, // when they're not all constants... @@ expression E1, E2, E3; constant C1, C2, C3; @@ ( kzalloc(C1 * C2 * C3, ...) | kzalloc( - (E1) * E2 * E3 + array3_size(E1, E2, E3) , ...) | kzalloc( - (E1) * (E2) * E3 + array3_size(E1, E2, E3) , ...) | kzalloc( - (E1) * (E2) * (E3) + array3_size(E1, E2, E3) , ...) | kzalloc( - E1 * E2 * E3 + array3_size(E1, E2, E3) , ...) ) // And then all remaining 2 factors products when they're not all constants, // keeping sizeof() as the second factor argument. @@ expression THING, E1, E2; type TYPE; constant C1, C2, C3; @@ ( kzalloc(sizeof(THING) * C2, ...) | kzalloc(sizeof(TYPE) * C2, ...) | kzalloc(C1 * C2 * C3, ...) | kzalloc(C1 * C2, ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * (E2) + E2, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(TYPE) * E2 + E2, sizeof(TYPE) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * (E2) + E2, sizeof(THING) , ...) | - kzalloc + kcalloc ( - sizeof(THING) * E2 + E2, sizeof(THING) , ...) | - kzalloc + kcalloc ( - (E1) * E2 + E1, E2 , ...) | - kzalloc + kcalloc ( - (E1) * (E2) + E1, E2 , ...) | - kzalloc + kcalloc ( - E1 * E2 + E1, E2 , ...) ) Signed-off-by: Kees Cook <keescook@chromium.org>
2018-06-13 00:03:40 +03:00
client.i2c_read_buffer = kzalloc(4, GFP_KERNEL);
if (!client.i2c_read_buffer) {
dprintk("%s: not enough memory\n", __func__);
ret = -ENOMEM;
goto error_memory_read;
}
client.i2c_buffer_lock = kzalloc(sizeof(struct mutex), GFP_KERNEL);
if (!client.i2c_buffer_lock) {
dprintk("%s: not enough memory\n", __func__);
ret = -ENOMEM;
goto error_memory_lock;
}
mutex_init(client.i2c_buffer_lock);
for (k = no_of_demods - 1; k >= 0; k--) {
/* designated i2c address */
new_addr = first_addr + (k << 1);
client.addr = new_addr;
if (!is_dib8096p)
dib8000_i2c_write16(&client, 1287, 0x0003); /* sram lead in, rdy */
if (dib8000_identify(&client) == 0) {
/* sram lead in, rdy */
if (!is_dib8096p)
dib8000_i2c_write16(&client, 1287, 0x0003);
client.addr = default_addr;
if (dib8000_identify(&client) == 0) {
dprintk("#%d: not identified\n", k);
ret = -EINVAL;
goto error;
}
}
/* start diversity to pull_down div_str - just for i2c-enumeration */
dib8000_i2c_write16(&client, 1286, (1 << 10) | (4 << 6));
/* set new i2c address and force divstart */
dib8000_i2c_write16(&client, 1285, (new_addr << 2) | 0x2);
client.addr = new_addr;
dib8000_identify(&client);
dprintk("IC %d initialized (to i2c_address 0x%x)\n", k, new_addr);
}
for (k = 0; k < no_of_demods; k++) {
new_addr = first_addr | (k << 1);
client.addr = new_addr;
// unforce divstr
dib8000_i2c_write16(&client, 1285, new_addr << 2);
/* deactivate div - it was just for i2c-enumeration */
dib8000_i2c_write16(&client, 1286, 0);
}
error:
kfree(client.i2c_buffer_lock);
error_memory_lock:
kfree(client.i2c_read_buffer);
error_memory_read:
kfree(client.i2c_write_buffer);
return ret;
}
static int dib8000_fe_get_tune_settings(struct dvb_frontend *fe, struct dvb_frontend_tune_settings *tune)
{
tune->min_delay_ms = 1000;
tune->step_size = 0;
tune->max_drift = 0;
return 0;
}
static void dib8000_release(struct dvb_frontend *fe)
{
struct dib8000_state *st = fe->demodulator_priv;
u8 index_frontend;
for (index_frontend = 1; (index_frontend < MAX_NUMBER_OF_FRONTENDS) && (st->fe[index_frontend] != NULL); index_frontend++)
dvb_frontend_detach(st->fe[index_frontend]);
dibx000_exit_i2c_master(&st->i2c_master);
i2c_del_adapter(&st->dib8096p_tuner_adap);
kfree(st->fe[0]);
kfree(st);
}
static struct i2c_adapter *dib8000_get_i2c_master(struct dvb_frontend *fe, enum dibx000_i2c_interface intf, int gating)
{
struct dib8000_state *st = fe->demodulator_priv;
return dibx000_get_i2c_adapter(&st->i2c_master, intf, gating);
}
static int dib8000_pid_filter_ctrl(struct dvb_frontend *fe, u8 onoff)
{
struct dib8000_state *st = fe->demodulator_priv;
u16 val = dib8000_read_word(st, 299) & 0xffef;
val |= (onoff & 0x1) << 4;
dprintk("pid filter enabled %d\n", onoff);
return dib8000_write_word(st, 299, val);
}
static int dib8000_pid_filter(struct dvb_frontend *fe, u8 id, u16 pid, u8 onoff)
{
struct dib8000_state *st = fe->demodulator_priv;
dprintk("Index %x, PID %d, OnOff %d\n", id, pid, onoff);
return dib8000_write_word(st, 305 + id, onoff ? (1 << 13) | pid : 0);
}
static const struct dvb_frontend_ops dib8000_ops = {
.delsys = { SYS_ISDBT },
.info = {
.name = "DiBcom 8000 ISDB-T",
.frequency_min_hz = 44250 * kHz,
.frequency_max_hz = 867250 * kHz,
.frequency_stepsize_hz = 62500,
.caps = FE_CAN_INVERSION_AUTO |
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_QPSK | FE_CAN_QAM_16 | FE_CAN_QAM_64 | FE_CAN_QAM_AUTO |
FE_CAN_TRANSMISSION_MODE_AUTO | FE_CAN_GUARD_INTERVAL_AUTO | FE_CAN_RECOVER | FE_CAN_HIERARCHY_AUTO,
},
.release = dib8000_release,
.init = dib8000_wakeup,
.sleep = dib8000_sleep,
.set_frontend = dib8000_set_frontend,
.get_tune_settings = dib8000_fe_get_tune_settings,
.get_frontend = dib8000_get_frontend,
.read_status = dib8000_read_status,
.read_ber = dib8000_read_ber,
.read_signal_strength = dib8000_read_signal_strength,
.read_snr = dib8000_read_snr,
.read_ucblocks = dib8000_read_unc_blocks,
};
static struct dvb_frontend *dib8000_init(struct i2c_adapter *i2c_adap, u8 i2c_addr, struct dib8000_config *cfg)
{
struct dvb_frontend *fe;
struct dib8000_state *state;
dprintk("dib8000_init\n");
state = kzalloc(sizeof(struct dib8000_state), GFP_KERNEL);
if (state == NULL)
return NULL;
fe = kzalloc(sizeof(struct dvb_frontend), GFP_KERNEL);
if (fe == NULL)
goto error;
memcpy(&state->cfg, cfg, sizeof(struct dib8000_config));
state->i2c.adap = i2c_adap;
state->i2c.addr = i2c_addr;
state->i2c.i2c_write_buffer = state->i2c_write_buffer;
state->i2c.i2c_read_buffer = state->i2c_read_buffer;
mutex_init(&state->i2c_buffer_lock);
state->i2c.i2c_buffer_lock = &state->i2c_buffer_lock;
state->gpio_val = cfg->gpio_val;
state->gpio_dir = cfg->gpio_dir;
/* Ensure the output mode remains at the previous default if it's
* not specifically set by the caller.
*/
if ((state->cfg.output_mode != OUTMODE_MPEG2_SERIAL) && (state->cfg.output_mode != OUTMODE_MPEG2_PAR_GATED_CLK))
state->cfg.output_mode = OUTMODE_MPEG2_FIFO;
state->fe[0] = fe;
fe->demodulator_priv = state;
memcpy(&state->fe[0]->ops, &dib8000_ops, sizeof(struct dvb_frontend_ops));
state->timf_default = cfg->pll->timf;
if (dib8000_identify(&state->i2c) == 0)
goto error;
dibx000_init_i2c_master(&state->i2c_master, DIB8000, state->i2c.adap, state->i2c.addr);
/* init 8096p tuner adapter */
strscpy(state->dib8096p_tuner_adap.name, "DiB8096P tuner interface",
sizeof(state->dib8096p_tuner_adap.name));
state->dib8096p_tuner_adap.algo = &dib8096p_tuner_xfer_algo;
state->dib8096p_tuner_adap.algo_data = NULL;
state->dib8096p_tuner_adap.dev.parent = state->i2c.adap->dev.parent;
i2c_set_adapdata(&state->dib8096p_tuner_adap, state);
i2c_add_adapter(&state->dib8096p_tuner_adap);
dib8000_reset(fe);
dib8000_write_word(state, 285, (dib8000_read_word(state, 285) & ~0x60) | (3 << 5)); /* ber_rs_len = 3 */
state->current_demod_bw = 6000;
return fe;
error:
kfree(state);
return NULL;
}
void *dib8000_attach(struct dib8000_ops *ops)
{
if (!ops)
return NULL;
ops->pwm_agc_reset = dib8000_pwm_agc_reset;
ops->get_dc_power = dib8090p_get_dc_power;
ops->set_gpio = dib8000_set_gpio;
ops->get_slave_frontend = dib8000_get_slave_frontend;
ops->set_tune_state = dib8000_set_tune_state;
ops->pid_filter_ctrl = dib8000_pid_filter_ctrl;
ops->get_adc_power = dib8000_get_adc_power;
ops->update_pll = dib8000_update_pll;
ops->tuner_sleep = dib8096p_tuner_sleep;
ops->get_tune_state = dib8000_get_tune_state;
ops->get_i2c_tuner = dib8096p_get_i2c_tuner;
ops->set_slave_frontend = dib8000_set_slave_frontend;
ops->pid_filter = dib8000_pid_filter;
ops->ctrl_timf = dib8000_ctrl_timf;
ops->init = dib8000_init;
ops->get_i2c_master = dib8000_get_i2c_master;
ops->i2c_enumeration = dib8000_i2c_enumeration;
ops->set_wbd_ref = dib8000_set_wbd_ref;
return ops;
}
EXPORT_SYMBOL(dib8000_attach);
MODULE_AUTHOR("Olivier Grenie <Olivier.Grenie@parrot.com, Patrick Boettcher <patrick.boettcher@posteo.de>");
MODULE_DESCRIPTION("Driver for the DiBcom 8000 ISDB-T demodulator");
MODULE_LICENSE("GPL");