use new E4000 tuner driver, allow manual gain

Many thanks to Hoernchen for making the driver work properly and adding manual gain! Signed-off-by: Steve Markgraf <steve@steve-m.de>
13 years ago · 86c34428aa
parent 0af094070f
commit 86c34428aa
11 changed files with 1328 additions and 2217 deletions
--- a/include/Makefile.am
+++ b/include/Makefile.am
@ -1,5 +1,5 @@
 rtlsdr_HEADERS = rtl-sdr.h rtl-sdr_export.h
-noinst_HEADERS = rtlsdr_i2c.h tuner_e4000.h tuner_fc0012.h tuner_fc0013.h tuner_fc2580.h
+noinst_HEADERS = rtlsdr_i2c.h tuner_e4k.h tuner_fc0012.h tuner_fc0013.h tuner_fc2580.h
 rtlsdrdir = $(includedir)
--- a/include/reg_field.h
+++ b/include/reg_field.h
@ -0,0 +1,60 @@
 #ifndef _REG_FIELD_H
 #define _REG_FIELD_H
 #include <stdint.h>
 #include <stdarg.h>
 enum cmd_op {
 	CMD_OP_GET	= (1 << 0),
 	CMD_OP_SET	= (1 << 1),
 	CMD_OP_EXEC	= (1 << 2),
 };
 enum pstate {
 	ST_IN_CMD,
 	ST_IN_ARG,
 };
 struct strbuf {
 	uint8_t idx;
 	char buf[32];
 };
 struct cmd_state {
 	struct strbuf cmd;
 	struct strbuf arg;
 	enum pstate state;
 	void (*out)(const char *format, va_list ap);
 };
 struct cmd {
 	const char *cmd;
 	uint32_t ops;
 	int (*cb)(struct cmd_state *cs, enum cmd_op op, const char *cmd,
 		  int argc, char **argv);
 	const char *help;
 };
 /* structure describing a field in a register */
 struct reg_field {
 	uint8_t reg;
 	uint8_t shift;
 	uint8_t width;
 };
 struct reg_field_ops {
 	const struct reg_field *fields;
 	const char **field_names;
 	uint32_t num_fields;
 	void *data;
 	int (*write_cb)(void *data, uint32_t reg, uint32_t val);
 	uint32_t (*read_cb)(void *data, uint32_t reg);
 };
 uint32_t reg_field_read(struct reg_field_ops *ops, struct reg_field *field);
 int reg_field_write(struct reg_field_ops *ops, struct reg_field *field, uint32_t val);
 int reg_field_cmd(struct cmd_state *cs, enum cmd_op op,
 		  const char *cmd, int argc, char **argv,
 		  struct reg_field_ops *ops);
 #endif
--- a/include/rtl-sdr.h
+++ b/include/rtl-sdr.h
@ -87,6 +87,8 @@ RTLSDR_API int rtlsdr_set_tuner_gain(rtlsdr_dev_t *dev, int gain);
 RTLSDR_API int rtlsdr_get_tuner_gain(rtlsdr_dev_t *dev);
 RTLSDR_API int rtlsdr_set_tuner_gain_mode(rtlsdr_dev_t *dev, int manual);
 /* this will select the baseband filters according to the requested sample rate */
 RTLSDR_API int rtlsdr_set_sample_rate(rtlsdr_dev_t *dev, uint32_t rate);
--- a/include/tuner_e4000.h
+++ b/include/tuner_e4000.h
@ -1,129 +0,0 @@
 #ifndef __TUNER_E4000_H
 #define __TUNER_E4000_H
 // Definition (implemeted for E4000)
 #define E4000_1_SUCCESS			1
 #define E4000_1_FAIL			0
 #define E4000_I2C_SUCCESS		1
 #define E4000_I2C_FAIL			0
 #define E4K_I2C_ADDR		0xc8
 #define E4K_CHECK_ADDR		0x02
 #define E4K_CHECK_VAL		0x40
 // Function (implemeted for E4000)
 int
 I2CReadByte(void *pTuner,
    unsigned char NoUse,
    unsigned char RegAddr,
    unsigned char *pReadingByte
    );
 int
 I2CWriteByte(
    void *pTuner,
 	unsigned char NoUse,
 	unsigned char RegAddr,
 	unsigned char WritingByte
 	);
 int
 I2CWriteArray(void *pTuner,
    unsigned char NoUse,
    unsigned char RegStartAddr,
    unsigned char ByteNum,
    unsigned char *pWritingBytes
    );
 // Functions (from E4000 source code)
 int tunerreset (void *pTuner);
 int Tunerclock(void *pTuner);
 int Qpeak(void *pTuner);
 int DCoffloop(void *pTuner);
 int GainControlinit(void *pTuner);
 int Gainmanual(void *pTuner);
 int E4000_gain_freq(void *pTuner, int frequency);
 int PLL(void *pTuner, int Ref_clk, int Freq);
 int LNAfilter(void *pTuner, int Freq);
 int IFfilter(void *pTuner, int bandwidth, int Ref_clk);
 int freqband(void *pTuner, int Freq);
 int DCoffLUT(void *pTuner);
 int GainControlauto(void *pTuner);
 int E4000_sensitivity(void *pTuner, int Freq, int bandwidth);
 int E4000_linearity(void *pTuner, int Freq, int bandwidth);
 int E4000_high_linearity(void *pTuner);
 int E4000_nominal(void *pTuner, int Freq, int bandwidth);
 // The following context is E4000 tuner API source code
 // Definitions
 // Bandwidth in Hz
 enum E4000_BANDWIDTH_HZ
 {
 	E4000_BANDWIDTH_6000000HZ = 6000000,
 	E4000_BANDWIDTH_7000000HZ = 7000000,
 	E4000_BANDWIDTH_8000000HZ = 8000000,
 };
 // Manipulaing functions
 void
 e4000_GetTunerType(
    void *pTuner,
 	int *pTunerType
 	);
 void
 e4000_GetDeviceAddr(
    void *pTuner,
 	unsigned char *pDeviceAddr
 	);
 int
 e4000_Initialize(
    void *pTuner
 	);
 int
 e4000_SetRfFreqHz(
    void *pTuner,
 	unsigned long RfFreqHz
 	);
 int
 e4000_GetRfFreqHz(
    void *pTuner,
 	unsigned long *pRfFreqHz
 	);
 // Extra manipulaing functions
 int
 e4000_GetRegByte(
    void *pTuner,
 	unsigned char RegAddr,
 	unsigned char *pReadingByte
 	);
 int
 e4000_SetBandwidthHz(
    void *pTuner,
 	unsigned long BandwidthHz
 	);
 int
 e4000_GetBandwidthHz(
    void *pTuner,
 	unsigned long *pBandwidthHz
 	);
 #endif
--- a/include/tuner_e4k.h
+++ b/include/tuner_e4k.h
@ -0,0 +1,219 @@
 #ifndef _E4K_TUNER_H
 #define _E4K_TUNER_H
 /* (C) 2011-2012 by Harald Welte <laforge@gnumonks.org>
 *
 * All Rights Reserved
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 3 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #define E4K_I2C_ADDR	0xc8
 #define E4K_CHECK_ADDR	0x02
 #define E4K_CHECK_VAL	0x40
 enum e4k_reg {
 	E4K_REG_MASTER1		= 0x00,
 	E4K_REG_MASTER2		= 0x01,
 	E4K_REG_MASTER3		= 0x02,
 	E4K_REG_MASTER4		= 0x03,
 	E4K_REG_MASTER5		= 0x04,
 	E4K_REG_CLK_INP		= 0x05,
 	E4K_REG_REF_CLK		= 0x06,
 	E4K_REG_SYNTH1		= 0x07,
 	E4K_REG_SYNTH2		= 0x08,
 	E4K_REG_SYNTH3		= 0x09,
 	E4K_REG_SYNTH4		= 0x0a,
 	E4K_REG_SYNTH5		= 0x0b,
 	E4K_REG_SYNTH6		= 0x0c,
 	E4K_REG_SYNTH7		= 0x0d,
 	E4K_REG_SYNTH8		= 0x0e,
 	E4K_REG_SYNTH9		= 0x0f,
 	E4K_REG_FILT1		= 0x10,
 	E4K_REG_FILT2		= 0x11,
 	E4K_REG_FILT3		= 0x12,
 	// gap
 	E4K_REG_GAIN1		= 0x14,
 	E4K_REG_GAIN2		= 0x15,
 	E4K_REG_GAIN3		= 0x16,
 	E4K_REG_GAIN4		= 0x17,
 	// gap
 	E4K_REG_AGC1		= 0x1a,
 	E4K_REG_AGC2		= 0x1b,
 	E4K_REG_AGC3		= 0x1c,
 	E4K_REG_AGC4		= 0x1d,
 	E4K_REG_AGC5		= 0x1e,
 	E4K_REG_AGC6		= 0x1f,
 	E4K_REG_AGC7		= 0x20,
 	E4K_REG_AGC8		= 0x21,
 	// gap
 	E4K_REG_AGC11		= 0x24,
 	E4K_REG_AGC12		= 0x25,
 	// gap
 	E4K_REG_DC1		= 0x29,
 	E4K_REG_DC2		= 0x2a,
 	E4K_REG_DC3		= 0x2b,
 	E4K_REG_DC4		= 0x2c,
 	E4K_REG_DC5		= 0x2d,
 	E4K_REG_DC6		= 0x2e,
 	E4K_REG_DC7		= 0x2f,
 	E4K_REG_DC8		= 0x30,
 	// gap
 	E4K_REG_QLUT0		= 0x50,
 	E4K_REG_QLUT1		= 0x51,
 	E4K_REG_QLUT2		= 0x52,
 	E4K_REG_QLUT3		= 0x53,
 	// gap
 	E4K_REG_ILUT0		= 0x60,
 	E4K_REG_ILUT1		= 0x61,
 	E4K_REG_ILUT2		= 0x62,
 	E4K_REG_ILUT3		= 0x63,
 	// gap
 	E4K_REG_DCTIME1		= 0x70,
 	E4K_REG_DCTIME2		= 0x71,
 	E4K_REG_DCTIME3		= 0x72,
 	E4K_REG_DCTIME4		= 0x73,
 	E4K_REG_PWM1		= 0x74,
 	E4K_REG_PWM2		= 0x75,
 	E4K_REG_PWM3		= 0x76,
 	E4K_REG_PWM4		= 0x77,
 	E4K_REG_BIAS		= 0x78,
 	E4K_REG_CLKOUT_PWDN	= 0x7a,
 	E4K_REG_CHFILT_CALIB	= 0x7b,
 	E4K_REG_I2C_REG_ADDR	= 0x7d,
 	// FIXME
 };
 #define E4K_MASTER1_RESET	(1 << 0)
 #define E4K_MASTER1_NORM_STBY	(1 << 1)
 #define E4K_MASTER1_POR_DET	(1 << 2)
 #define E4K_SYNTH1_PLL_LOCK	(1 << 0)
 #define E4K_SYNTH1_BAND_SHIF	1
 #define E4K_SYNTH7_3PHASE_EN	(1 << 3)
 #define E4K_SYNTH8_VCOCAL_UPD	(1 << 2)
 #define E4K_FILT3_DISABLE	(1 << 5)
 #define E4K_AGC1_LIN_MODE	(1 << 4)
 #define E4K_AGC1_LNA_UPDATE	(1 << 5)
 #define E4K_AGC1_LNA_G_LOW	(1 << 6)
 #define E4K_AGC1_LNA_G_HIGH	(1 << 7)
 #define E4K_AGC6_LNA_CAL_REQ	(1 << 4)
 #define E4K_AGC7_MIX_GAIN_AUTO	(1 << 0)
 #define E4K_AGC7_GAIN_STEP_5dB	(1 << 5)
 #define E4K_AGC8_SENS_LIN_AUTO	(1 << 0)
 #define E4K_AGC11_LNA_GAIN_ENH	(1 << 0)
 #define E4K_DC1_CAL_REQ		(1 << 0)
 #define E4K_DC5_I_LUT_EN	(1 << 0)
 #define E4K_DC5_Q_LUT_EN	(1 << 1)
 #define E4K_DC5_RANGE_DET_EN	(1 << 2)
 #define E4K_DC5_RANGE_EN	(1 << 3)
 #define E4K_DC5_TIMEVAR_EN	(1 << 4)
 #define E4K_CLKOUT_DISABLE	0x96
 #define E4K_CHFCALIB_CMD	(1 << 0)
 #define E4K_AGC1_MOD_MASK	0xF
 enum e4k_agc_mode {
 	E4K_AGC_MOD_SERIAL		= 0x0,
 	E4K_AGC_MOD_IF_PWM_LNA_SERIAL	= 0x1,
 	E4K_AGC_MOD_IF_PWM_LNA_AUTONL	= 0x2,
 	E4K_AGC_MOD_IF_PWM_LNA_SUPERV	= 0x3,
 	E4K_AGC_MOD_IF_SERIAL_LNA_PWM	= 0x4,
 	E4K_AGC_MOD_IF_PWM_LNA_PWM	= 0x5,
 	E4K_AGC_MOD_IF_DIG_LNA_SERIAL	= 0x6,
 	E4K_AGC_MOD_IF_DIG_LNA_AUTON	= 0x7,
 	E4K_AGC_MOD_IF_DIG_LNA_SUPERV	= 0x8,
 	E4K_AGC_MOD_IF_SERIAL_LNA_AUTON	= 0x9,
 	E4K_AGC_MOD_IF_SERIAL_LNA_SUPERV = 0xa,
 };
 enum e4k_band {
 	E4K_BAND_VHF2	= 0,
 	E4K_BAND_VHF3	= 1,
 	E4K_BAND_UHF	= 2,
 	E4K_BAND_L	= 3,
 };
 enum e4k_mixer_filter_bw {
 	E4K_F_MIX_BW_27M	= 0,
 	E4K_F_MIX_BW_4M6	= 8,
 	E4K_F_MIX_BW_4M2	= 9,
 	E4K_F_MIX_BW_3M8	= 10,
 	E4K_F_MIX_BW_3M4	= 11,
 	E4K_F_MIX_BW_3M		= 12,
 	E4K_F_MIX_BW_2M7	= 13,
 	E4K_F_MIX_BW_2M3	= 14,
 	E4K_F_MIX_BW_1M9	= 15,
 };
 enum e4k_if_filter {
 	E4K_IF_FILTER_MIX,
 	E4K_IF_FILTER_CHAN,
 	E4K_IF_FILTER_RC
 };
 struct e4k_pll_params {
 	uint32_t fosc;
 	uint32_t intended_flo;
 	uint32_t flo;
 	uint16_t x;
 	uint8_t z;
 	uint8_t r;
 	uint8_t r_idx;
 	uint8_t threephase;
 };
 struct e4k_state {
 	void *i2c_dev;
 	uint8_t i2c_addr;
 	enum e4k_band band;
 	struct e4k_pll_params vco;
 	void *rtl_dev;
 };
 int e4k_init(struct e4k_state *e4k);
 int e4k_if_gain_set(struct e4k_state *e4k, uint8_t stage, int8_t value);
 int e4k_mixer_gain_set(struct e4k_state *e4k, int8_t value);
 int e4k_commonmode_set(struct e4k_state *e4k, int8_t value);
 int e4k_tune_freq(struct e4k_state *e4k, uint32_t freq);
 int e4k_tune_params(struct e4k_state *e4k, struct e4k_pll_params *p);
 int e4k_compute_pll_params(struct e4k_pll_params *oscp, uint32_t fosc, uint32_t intended_flo);
 int e4k_if_filter_bw_get(struct e4k_state *e4k, enum e4k_if_filter filter);
 int e4k_if_filter_bw_set(struct e4k_state *e4k, enum e4k_if_filter filter,
 		         uint32_t bandwidth);
 int e4k_if_filter_chan_enable(struct e4k_state *e4k, int on);
 int e4k_rf_filter_set(struct e4k_state *e4k);
 int e4k_reg_write(struct e4k_state *e4k, uint8_t reg, uint8_t val);
 uint8_t e4k_reg_read(struct e4k_state *e4k, uint8_t reg);
 int e4k_manual_dc_offset(struct e4k_state *e4k, int8_t iofs, int8_t irange, int8_t qofs, int8_t qrange);
 int e4k_dc_offset_calibrate(struct e4k_state *e4k);
 int e4k_dc_offset_gen_table(struct e4k_state *e4k);
 int e4k_set_lna_gain(struct e4k_state *e4k, int32_t gain);
 int e4k_enable_manual_gain(struct e4k_state *e4k, uint8_t manual);
 int e4k_set_enh_gain(struct e4k_state *e4k, int32_t gain);
 #endif /* _E4K_TUNER_H */
--- a/src/CMakeLists.txt
+++ b/src/CMakeLists.txt
@ -22,7 +22,7 @@
 ########################################################################
 add_library(rtlsdr_shared SHARED
    rtl-sdr.c
-    tuner_e4000.c
+    tuner_e4k.c
    tuner_fc0012.c
    tuner_fc0013.c
    tuner_fc2580.c
@ -37,7 +37,7 @@ set_target_properties(rtlsdr_shared PROPERTIES OUTPUT_NAME rtlsdr)
 add_library(rtlsdr_static STATIC
    rtl-sdr.c
-    tuner_e4000.c
+    tuner_e4k.c
    tuner_fc0012.c
    tuner_fc0013.c
    tuner_fc2580.c
--- a/src/Makefile.am
+++ b/src/Makefile.am
@ -7,7 +7,7 @@ AM_CFLAGS = -fPIC -Wall
 lib_LTLIBRARIES = librtlsdr.la
-librtlsdr_la_SOURCES = rtl-sdr.c tuner_e4000.c tuner_fc0012.c tuner_fc0013.c tuner_fc2580.c
+librtlsdr_la_SOURCES = rtl-sdr.c tuner_e4k.c tuner_fc0012.c tuner_fc0013.c tuner_fc2580.c
 librtlsdr_la_LDFALGS = -version-info $(LIBVERSION)
 bin_PROGRAMS         = rtl_sdr rtl_tcp
--- a/src/rtl-sdr.c
+++ b/src/rtl-sdr.c
@ -25,6 +25,7 @@
 #include <math.h>
 #ifndef _WIN32
 #include <unistd.h>
 #define min(a, b) (((a) < (b)) ? (a) : (b))
 #endif
 #include <libusb.h>
@ -40,7 +41,7 @@
 #endif
 #include "rtl-sdr.h"
-#include "tuner_e4000.h"
+#include "tuner_e4k.h"
 #include "tuner_fc0012.h"
 #include "tuner_fc0013.h"
 #include "tuner_fc2580.h"
@ -52,6 +53,7 @@ typedef struct rtlsdr_tuner {
 	int (*set_freq)(void *, uint32_t freq /* Hz */);
 	int (*set_bw)(void *, int bw /* Hz */);
 	int (*set_gain)(void *, int gain /* dB */);
 	int (*set_gain_mode)(void *, int manual);
 } rtlsdr_tuner_t;
 enum rtlsdr_async_status {
@ -79,20 +81,48 @@ struct rtlsdr_dev {
 	uint32_t freq; /* Hz */
 	int corr; /* ppm */
 	int gain; /* dB */
 	struct e4k_state e4k_s;
 };
 void rtlsdr_set_gpio_bit(rtlsdr_dev_t *dev, uint8_t gpio, int val);
 /* generic tuner interface functions, shall be moved to the tuner implementations */
-int e4k_init(void *dev) { return e4000_Initialize(dev); }
+int e4000_init(void *dev) {
-int e4k_exit(void *dev) { return 0; }
+	rtlsdr_dev_t* devt = (rtlsdr_dev_t*)dev;
-int e4k_set_freq(void *dev, uint32_t freq) {
+	devt->e4k_s.i2c_addr = E4K_I2C_ADDR;
-	return e4000_SetRfFreqHz(dev, freq);
+	devt->e4k_s.vco.fosc = devt->tun_xtal;
 	devt->e4k_s.rtl_dev = dev;
 	return e4k_init(&devt->e4k_s);
 }
-int e4k_set_bw(void *dev, int bw) {
+int e4000_exit(void *dev) { return 0; }
-	return e4000_SetBandwidthHz(dev, 4000000);
+int e4000_set_freq(void *dev, uint32_t freq) {
 	rtlsdr_dev_t* devt = (rtlsdr_dev_t*)dev;
 	return e4k_tune_freq(&devt->e4k_s, freq);
 }
 int e4000_set_bw(void *dev, int bw) {
 	return 0;
 }
 int e4000_set_gain(void *dev, int gain) {
 	int rc;
 	rtlsdr_dev_t* devt = (rtlsdr_dev_t*)dev;
 	int mixgain = (gain > 340) ? 12 : 4;
 	int enhgain = (gain - 420);
 	if(e4k_set_lna_gain(&devt->e4k_s, min(300, gain - 40)) == -EINVAL)
 		return -1;
 	if(e4k_mixer_gain_set(&devt->e4k_s, mixgain) == -EINVAL)
 		return -1;
 	if(enhgain >= 0)
 		if(e4k_set_enh_gain(&devt->e4k_s, enhgain) == -EINVAL)
 			return -1;
 	return 0;
 }
 int e4000_set_gain_mode(void *dev, int manual) {
 	rtlsdr_dev_t* devt = (rtlsdr_dev_t*)dev;
 	e4k_enable_manual_gain(&devt->e4k_s, manual);
 	return 0;
 }
 int e4k_set_gain(void *dev, int gain) { return 0; }
 int fc0012_init(void *dev) { return FC0012_Open(dev); }
 int fc0012_exit(void *dev) { return 0; }
@ -105,6 +135,7 @@ int fc0012_set_bw(void *dev, int bw) {
 	return FC0012_SetFrequency(dev, ((rtlsdr_dev_t *) dev)->freq/1000, 6);
 }
 int fc0012_set_gain(void *dev, int gain) { return 0; }
 int fc0012_set_gain_mode(void *dev, int manual) { return 0; }
 int fc0013_init(void *dev) { return FC0013_Open(dev); }
 int fc0013_exit(void *dev) { return 0; }
@ -115,6 +146,7 @@ int fc0013_set_bw(void *dev, int bw) {
 	return FC0013_SetFrequency(dev, ((rtlsdr_dev_t *) dev)->freq/1000, 6);
 }
 int fc0013_set_gain(void *dev, int gain) { return 0; }
 int fc0013_set_gain_mode(void *dev, int manual) { return 0; }
 int fc2580_init(void *dev) { return fc2580_Initialize(dev); }
 int fc2580_exit(void *dev) { return 0; }
@ -125,6 +157,7 @@ int fc2580_set_bw(void *dev, int bw) {
 	return fc2580_SetBandwidthMode(dev, 1);
 }
 int fc2580_set_gain(void *dev, int gain) { return 0; }
 int fc2580_set_gain_mode(void *dev, int manual) { return 0; }
 enum rtlsdr_tuners {
 	RTLSDR_TUNER_E4000,
@ -135,20 +168,24 @@ enum rtlsdr_tuners {
 static rtlsdr_tuner_t tuners[] = {
 	{
-		e4k_init, e4k_exit,
+		e4000_init, e4000_exit,
-		e4k_set_freq, e4k_set_bw, e4k_set_gain
+		e4000_set_freq, e4000_set_bw, e4000_set_gain,
 		e4000_set_gain_mode
 	},
 	{
 		fc0012_init, fc0012_exit,
-		fc0012_set_freq, fc0012_set_bw, fc0012_set_gain
+		fc0012_set_freq, fc0012_set_bw, fc0012_set_gain,
 		fc0012_set_gain_mode
 	},
 	{
 		fc0013_init, fc0013_exit,
-		fc0013_set_freq, fc0013_set_bw, fc0013_set_gain
+		fc0013_set_freq, fc0013_set_bw, fc0013_set_gain,
 		fc0013_set_gain_mode
 	},
 	{
 		fc2580_init, fc2580_exit,
-		_fc2580_set_freq, fc2580_set_bw, fc2580_set_gain
+		_fc2580_set_freq, fc2580_set_bw, fc2580_set_gain,
 		fc2580_set_gain_mode
 	},
 };
@ -277,6 +314,16 @@ uint8_t rtlsdr_i2c_read_reg(rtlsdr_dev_t *dev, uint8_t i2c_addr, uint8_t reg)
 	return data;
 }
 /* TODO clean this up again */
 int e4k_reg_write(struct e4k_state *e4k, uint8_t reg, uint8_t val)
 {
 	return rtlsdr_i2c_write_reg((rtlsdr_dev_t*)e4k->rtl_dev, e4k->i2c_addr, reg, val);}
 uint8_t e4k_reg_read(struct e4k_state *e4k, uint8_t reg)
 {
 	return rtlsdr_i2c_read_reg((rtlsdr_dev_t*)e4k->rtl_dev, e4k->i2c_addr, reg);
 }
 int rtlsdr_i2c_write(rtlsdr_dev_t *dev, uint8_t i2c_addr, uint8_t *buffer, int len)
 {
 	uint16_t addr = i2c_addr;
@ -594,8 +641,11 @@ int rtlsdr_set_tuner_gain(rtlsdr_dev_t *dev, int gain)
 	if (!dev || !dev->tuner)
 		return -1;
-	if (dev->tuner->set_gain)
+	if (dev->tuner->set_gain) {
 		rtlsdr_set_i2c_repeater(dev, 1);
 		r = dev->tuner->set_gain((void *)dev, gain);
 		rtlsdr_set_i2c_repeater(dev, 0);
 	}
 	if (!r)
 		dev->gain = gain;
@ -611,6 +661,24 @@ int rtlsdr_get_tuner_gain(rtlsdr_dev_t *dev)
 	return dev->gain;
 }
 int rtlsdr_set_tuner_gain_mode(rtlsdr_dev_t *dev, int mode)
 {
 	int r = 0;
 	if (!dev || !dev->tuner)
 		return -1;
 	if (dev->tuner->set_gain_mode) {
 		rtlsdr_set_i2c_repeater(dev, 1);
 		r = dev->tuner->set_gain_mode((void *)dev, mode);
 		rtlsdr_set_i2c_repeater(dev, 0);
 	}
 	return r;
 }
 int rtlsdr_set_sample_rate(rtlsdr_dev_t *dev, uint32_t samp_rate)
 {
 	uint16_t tmp;
@ -862,8 +930,6 @@ err:
 int rtlsdr_close(rtlsdr_dev_t *dev)
 {
 	int i;
 	if (!dev)
 		return -1;
--- a/src/rtl_tcp.c
+++ b/src/rtl_tcp.c
@ -32,6 +32,8 @@
 #include <sys/socket.h>
 #include <netinet/in.h>
 #include <fcntl.h>
 #else
 #include <WinSock2.h>
 #endif
 #include <pthread.h>
@ -278,6 +280,9 @@ static void *command_worker(void *arg)
 			printf("set freq %d\n", cmd.param);
 			rtlsdr_set_center_freq(dev, cmd.param);
 			break;
 		case 0x04:
 			 rtlsdr_set_tuner_gain(dev, cmd.param);
 			 break;
 		default:
 			break;
 		}
@ -293,7 +298,7 @@ int main(int argc, char **argv)
 	uint32_t frequency = 0, samp_rate = 2048000;
 	struct sockaddr_in local, remote;
 	int device_count;
-	uint32_t dev_index = 0, gain = 5;
+	uint32_t dev_index = 0, gain = -10;
 	struct llist *curelem,*prev;
 	pthread_attr_t attr;
 	void *status;
--- a/src/tuner_e4000.c
+++ b/src/tuner_e4000.c
--- a/src/tuner_e4k.c
+++ b/src/tuner_e4k.c
@ -0,0 +1,955 @@
 /* (C) 2011-2012 by Harald Welte <laforge@gnumonks.org>
 *
 * All Rights Reserved
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 3 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <limits.h>
 #include <stdint.h>
 #include <errno.h>
 #include <string.h>
 #include <stdio.h>
 #include <reg_field.h>
 #include <tuner_e4k.h>
 #define ARRAY_SIZE(arr) (sizeof(arr) / sizeof((arr)[0]))
 /* If this is defined, the limits are somewhat relaxed compared to what the
 * vendor claims is possible */
 #define OUT_OF_SPEC
 #define MHZ(x)	((x)*1000*1000)
 #define KHZ(x)	((x)*1000)
 uint32_t unsigned_delta(uint32_t a, uint32_t b)
 {
 	if (a > b)
 		return a - b;
 	else
 		return b - a;
 }
 /* look-up table bit-width -> mask */
 static const uint8_t width2mask[] = {
 	0, 1, 3, 7, 0xf, 0x1f, 0x3f, 0x7f, 0xff
 };
 /***********************************************************************
 * Register Access */
 #if 0
 /*! \brief Write a register of the tuner chip
 *  \param[in] e4k reference to the tuner
 *  \param[in] reg number of the register
 *  \param[in] val value to be written
 *  \returns 0 on success, negative in case of error
 */
 int e4k_reg_write(struct e4k_state *e4k, uint8_t reg, uint8_t val)
 {
 	/* FIXME */
 	return 0;
 }
 /*! \brief Read a register of the tuner chip
 *  \param[in] e4k reference to the tuner
 *  \param[in] reg number of the register
 *  \returns positive 8bit register contents on success, negative in case of error
 */
 int e4k_reg_read(struct e4k_state *e4k, uint8_t reg)
 {
 	/* FIXME */
 	return 0;
 }
 #endif
 /*! \brief Set or clear some (masked) bits inside a register
 *  \param[in] e4k reference to the tuner
 *  \param[in] reg number of the register
 *  \param[in] mask bit-mask of the value
 *  \param[in] val data value to be written to register
 *  \returns 0 on success, negative in case of error
 */
 static int e4k_reg_set_mask(struct e4k_state *e4k, uint8_t reg,
 		     uint8_t mask, uint8_t val)
 {
 	uint8_t tmp = e4k_reg_read(e4k, reg);
 	if ((tmp & mask) == val)
 		return 0;
 	return e4k_reg_write(e4k, reg, (tmp & ~mask) | (val & mask));
 }
 /*! \brief Write a given field inside a register
 *  \param[in] e4k reference to the tuner
 *  \param[in] field structure describing the field
 *  \param[in] val value to be written
 *  \returns 0 on success, negative in case of error
 */
 static int e4k_field_write(struct e4k_state *e4k, const struct reg_field *field, uint8_t val)
 {
 	int rc;
 	uint8_t mask;
 	rc = e4k_reg_read(e4k, field->reg);
 	if (rc < 0)
 		return rc;
 	mask = width2mask[field->width] << field->shift;
 	return e4k_reg_set_mask(e4k, field->reg, mask, val << field->shift);
 }
 /*! \brief Read a given field inside a register
 *  \param[in] e4k reference to the tuner
 *  \param[in] field structure describing the field
 *  \returns positive value of the field, negative in case of error
 */
 static int e4k_field_read(struct e4k_state *e4k, const struct reg_field *field)
 {
 	int rc;
 	rc = e4k_reg_read(e4k, field->reg);
 	if (rc < 0)
 		return rc;
 	rc = (rc >> field->shift) & width2mask[field->width];
 	return rc;
 }
 /***********************************************************************
 * Filter Control */
 static const uint32_t rf_filt_center_uhf[] = {
 	MHZ(360), MHZ(380), MHZ(405), MHZ(425),
 	MHZ(450), MHZ(475), MHZ(505), MHZ(540),
 	MHZ(575), MHZ(615), MHZ(670), MHZ(720),
 	MHZ(760), MHZ(840), MHZ(890), MHZ(970)
 };
 static const uint32_t rf_filt_center_l[] = {
 	MHZ(1300), MHZ(1320), MHZ(1360), MHZ(1410),
 	MHZ(1445), MHZ(1460), MHZ(1490), MHZ(1530),
 	MHZ(1560), MHZ(1590), MHZ(1640), MHZ(1660),
 	MHZ(1680), MHZ(1700), MHZ(1720), MHZ(1750)
 };
 static int closest_arr_idx(const uint32_t *arr, unsigned int arr_size, uint32_t freq)
 {
 	unsigned int i, bi = 0;
 	uint32_t best_delta = 0xffffffff;
 	/* iterate over the array containing a list of the center
 	 * frequencies, selecting the closest one */
 	for (i = 0; i < arr_size; i++) {
 		uint32_t delta = unsigned_delta(freq, arr[i]);
 		if (delta < best_delta) {
 			best_delta = delta;
 			bi = i;
 		}
 	}
 	return bi;
 }
 /* return 4-bit index as to which RF filter to select */
 static int choose_rf_filter(uint32_t freq)
 {
 	int rc;
 	if (freq < MHZ(350))
 		rc = 0;
 	else if (freq < MHZ(1000))
 		rc = closest_arr_idx(rf_filt_center_uhf,
 				     ARRAY_SIZE(rf_filt_center_uhf),
 				     freq);
 	else
 		rc = closest_arr_idx(rf_filt_center_l,
 				     ARRAY_SIZE(rf_filt_center_l),
 				     freq);
 	return rc;
 }
 /* \brief Automatically select apropriate RF filter based on e4k state */
 int e4k_rf_filter_set(struct e4k_state *e4k)
 {
 	int rc;
 	rc = choose_rf_filter(e4k->vco.flo);
 	if (rc < 0)
 		return rc;
 	return e4k_reg_set_mask(e4k, E4K_REG_FILT1, 0xF, rc);
 }
 /* Mixer Filter */
 static const uint32_t mix_filter_bw[] = {
 	KHZ(27000), KHZ(27000), KHZ(27000), KHZ(27000),
 	KHZ(27000), KHZ(27000), KHZ(27000), KHZ(27000),
 	KHZ(4600), KHZ(4200), KHZ(3800), KHZ(3400),
 	KHZ(3300), KHZ(2700), KHZ(2300), KHZ(1900)
 };
 /* IF RC Filter */
 static const uint32_t ifrc_filter_bw[] = {
 	KHZ(21400), KHZ(21000), KHZ(17600), KHZ(14700),
 	KHZ(12400), KHZ(10600), KHZ(9000), KHZ(7700),
 	KHZ(6400), KHZ(5300), KHZ(4400), KHZ(3400),
 	KHZ(2600), KHZ(1800), KHZ(1200), KHZ(1000)
 };
 /* IF Channel Filter */
 static const uint32_t ifch_filter_bw[] = {
 	KHZ(5500), KHZ(5300), KHZ(5000), KHZ(4800),
 	KHZ(4600), KHZ(4400), KHZ(4300), KHZ(4100),
 	KHZ(3900), KHZ(3800), KHZ(3700), KHZ(3600),
 	KHZ(3400), KHZ(3300), KHZ(3200), KHZ(3100),
 	KHZ(3000), KHZ(2950), KHZ(2900), KHZ(2800),
 	KHZ(2750), KHZ(2700), KHZ(2600), KHZ(2550),
 	KHZ(2500), KHZ(2450), KHZ(2400), KHZ(2300),
 	KHZ(2280), KHZ(2240), KHZ(2200), KHZ(2150)
 };
 static const uint32_t *if_filter_bw[] = {
 	mix_filter_bw,
 	ifch_filter_bw,
 	ifrc_filter_bw,
 };
 static const uint32_t if_filter_bw_len[] = {
 	ARRAY_SIZE(mix_filter_bw),
 	ARRAY_SIZE(ifch_filter_bw),
 	ARRAY_SIZE(ifrc_filter_bw),
 };
 static const struct reg_field if_filter_fields[] = {
 	{
 		E4K_REG_FILT2, 4, 4,
 	},
 	{
 		E4K_REG_FILT3, 0, 5,
 	},
 	{
 		E4K_REG_FILT2, 0, 4,
 	}
 };
 static int find_if_bw(enum e4k_if_filter filter, uint32_t bw)
 {
 	if (filter >= ARRAY_SIZE(if_filter_bw))
 		return -EINVAL;
 	return closest_arr_idx(if_filter_bw[filter],
 			       if_filter_bw_len[filter], bw);
 }
 /*! \brief Set the filter band-width of any of the IF filters
 *  \param[in] e4k reference to the tuner chip
 *  \param[in] filter filter to be configured
 *  \param[in] bandwidth bandwidth to be configured
 *  \returns positive actual filter band-width, negative in case of error
 */
 int e4k_if_filter_bw_set(struct e4k_state *e4k, enum e4k_if_filter filter,
 		         uint32_t bandwidth)
 {
 	int bw_idx;
 	const struct reg_field *field;
 	if (filter >= ARRAY_SIZE(if_filter_bw))
 		return -EINVAL;
 	bw_idx = find_if_bw(filter, bandwidth);
 	field = &if_filter_fields[filter];
 	return e4k_field_write(e4k, field, bw_idx);
 }
 /*! \brief Enables / Disables the channel filter
 *  \param[in] e4k reference to the tuner chip
 *  \param[in] on 1=filter enabled, 0=filter disabled
 *  \returns 0 success, negative errors
 */
 int e4k_if_filter_chan_enable(struct e4k_state *e4k, int on)
 {
 	return e4k_reg_set_mask(e4k, E4K_REG_FILT3, E4K_FILT3_DISABLE,
 	                        on ? 0 : E4K_FILT3_DISABLE);
 }
 int e4k_if_filter_bw_get(struct e4k_state *e4k, enum e4k_if_filter filter)
 {
 	const uint32_t *arr;
 	int rc;
 	const struct reg_field *field;
 	if (filter >= ARRAY_SIZE(if_filter_bw))
 		return -EINVAL;
 	field = &if_filter_fields[filter];
 	rc = e4k_field_read(e4k, field);
 	if (rc < 0)
 		return rc;
 	arr = if_filter_bw[filter];
 	return arr[rc];
 }
 /***********************************************************************
 * Frequency Control */
 #define E4K_FVCO_MIN_KHZ	2600000	/* 2.6 GHz */
 #define E4K_FVCO_MAX_KHZ	3900000	/* 3.9 GHz */
 #define E4K_PLL_Y		65536
 #ifdef OUT_OF_SPEC
 #define E4K_FLO_MIN_MHZ		50
 #define E4K_FLO_MAX_MHZ		2200UL
 #else
 #define E4K_FLO_MIN_MHZ		64
 #define E4K_FLO_MAX_MHZ		1700
 #endif
 struct pll_settings {
 	uint32_t freq;
 	uint8_t reg_synth7;
 	uint8_t mult;
 };
 static const struct pll_settings pll_vars[] = {
 	{KHZ(72400),	(1 << 3) | 7,	48},
 	{KHZ(81200),	(1 << 3) | 6,	40},
 	{KHZ(108300),	(1 << 3) | 5,	32},
 	{KHZ(162500),	(1 << 3) | 4,	24},
 	{KHZ(216600),	(1 << 3) | 3,	16},
 	{KHZ(325000),	(1 << 3) | 2,	12},
 	{KHZ(350000),	(1 << 3) | 1,	8},
 	{KHZ(432000),	(0 << 3) | 3,	8},
 	{KHZ(667000),	(0 << 3) | 2,	6},
 	{KHZ(1200000),	(0 << 3) | 1,	4}
 };
 static int is_fvco_valid(uint32_t fvco_z)
 {
 	/* check if the resulting fosc is valid */
 	if (fvco_z/1000 < E4K_FVCO_MIN_KHZ ||
 	    fvco_z/1000 > E4K_FVCO_MAX_KHZ) {
 		fprintf(stderr, "Fvco %u invalid\n", fvco_z);
 		return 0;
 	}
 	return 1;
 }
 static int is_fosc_valid(uint32_t fosc)
 {
 	if (fosc < MHZ(16) || fosc > MHZ(30)) {
 		fprintf(stderr, "Fosc %u invalid\n", fosc);
 		return 0;
 	}
 	return 1;
 }
 static int is_z_valid(uint32_t z)
 {
 	if (z > 255) {
 		fprintf(stderr, "Z %u invalid\n", z);
 		return 0;
 	}
 	return 1;
 }
 /*! \brief Determine if 3-phase mixing shall be used or not */
 static int use_3ph_mixing(uint32_t flo)
 {
 	/* this is a magic number somewhre between VHF and UHF */
 	if (flo < MHZ(350))
 		return 1;
 	return 0;
 }
 /* \brief compute Fvco based on Fosc, Z and X
 * \returns positive value (Fvco in Hz), 0 in case of error */
 static uint64_t compute_fvco(uint32_t f_osc, uint8_t z, uint16_t x)
 {
 	uint64_t fvco_z, fvco_x, fvco;
 	/* We use the following transformation in order to
 	 * handle the fractional part with integer arithmetic:
 	 *  Fvco = Fosc * (Z + X/Y) <=> Fvco = Fosc * Z + (Fosc * X)/Y
 	 * This avoids X/Y = 0.  However, then we would overflow a 32bit
 	 * integer, as we cannot hold e.g. 26 MHz * 65536 either.
 	 */
 	fvco_z = (uint64_t)f_osc * z;
 #if 0
 	if (!is_fvco_valid(fvco_z))
 		return 0;
 #endif
 	fvco_x = ((uint64_t)f_osc * x) / E4K_PLL_Y;
 	fvco = fvco_z + fvco_x;
 	return fvco;
 }
 static int compute_flo(uint32_t f_osc, uint8_t z, uint16_t x, uint8_t r)
 {
 	uint64_t fvco = compute_fvco(f_osc, z, x);
 	if (fvco == 0)
 		return -EINVAL;
 	return fvco / r;
 }
 static int e4k_band_set(struct e4k_state *e4k, enum e4k_band band)
 {
 	int rc;
 	switch (band) {
 	case E4K_BAND_VHF2:
 	case E4K_BAND_VHF3:
 	case E4K_BAND_UHF:
 		e4k_reg_write(e4k, E4K_REG_BIAS, 3);
 		break;
 	case E4K_BAND_L:
 		e4k_reg_write(e4k, E4K_REG_BIAS, 0);
 		break;
 	}
 	rc = e4k_reg_set_mask(e4k, E4K_REG_SYNTH1, 0x06, band << 1);
 	if (rc >= 0)
 		e4k->band = band;
 	return rc;
 }
 /*! \brief Compute PLL parameters for givent target frequency
 *  \param[out] oscp Oscillator parameters, if computation successful
 *  \param[in] fosc Clock input frequency applied to the chip (Hz)
 *  \param[in] intended_flo target tuning frequency (Hz)
 *  \returns actual PLL frequency, as close as possible to intended_flo,
 *	     negative in case of error
 */
 int e4k_compute_pll_params(struct e4k_pll_params *oscp, uint32_t fosc, uint32_t intended_flo)
 {
 	uint32_t i;
 	uint8_t r = 2;
 	uint64_t intended_fvco, remainder;
 	uint64_t z = 0;
 	uint32_t x;
 	int flo;
 	int three_phase_mixing = 0;
 	oscp->r_idx = 0;
 	if (!is_fosc_valid(fosc))
 		return -EINVAL;
 	for(i = 0; i < ARRAY_SIZE(pll_vars); ++i) {
 		if(intended_flo < pll_vars[i].freq) {
 			three_phase_mixing = (pll_vars[i].reg_synth7 & 0x08) ? 1 : 0;
 			oscp->r_idx = pll_vars[i].reg_synth7;
 			r = pll_vars[i].mult;
 			break;
 		}
 	}
 	//fprintf(stderr, "Fint=%u, R=%u\n", intended_flo, r);
 	/* flo(max) = 1700MHz, R(max) = 48, we need 64bit! */
 	intended_fvco = (uint64_t)intended_flo * r;
 	/* compute integral component of multiplier */
 	z = intended_fvco / fosc;
 	/* compute fractional part.  this will not overflow,
 	* as fosc(max) = 30MHz and z(max) = 255 */
 	remainder = intended_fvco - (fosc * z);
 	/* remainder(max) = 30MHz, E4K_PLL_Y = 65536 -> 64bit! */
 	x = (remainder * E4K_PLL_Y) / fosc;
 	/* x(max) as result of this computation is 65536 */
 	flo = compute_flo(fosc, z, x, r);
 	oscp->fosc = fosc;
 	oscp->flo = flo;
 	oscp->intended_flo = intended_flo;
 	oscp->r = r;
 //	oscp->r_idx = pll_vars[i].reg_synth7 & 0x0;
 	oscp->threephase = three_phase_mixing;
 	oscp->x = x;
 	oscp->z = z;
 	return flo;
 }
 int e4k_tune_params(struct e4k_state *e4k, struct e4k_pll_params *p)
 {
 	uint8_t val;
 	/* program R + 3phase/2phase */
 	e4k_reg_write(e4k, E4K_REG_SYNTH7, p->r_idx);
 	/* program Z */
 	e4k_reg_write(e4k, E4K_REG_SYNTH3, p->z);
 	/* program X */
 	e4k_reg_write(e4k, E4K_REG_SYNTH4, p->x & 0xff);
 	e4k_reg_write(e4k, E4K_REG_SYNTH5, p->x >> 8);
 	/* we're in auto calibration mode, so there's no need to trigger it */
 	memcpy(&e4k->vco, p, sizeof(e4k->vco));
 	/* set the band */
 	if (e4k->vco.flo < MHZ(140))
 		e4k_band_set(e4k, E4K_BAND_VHF2);
 	else if (e4k->vco.flo < MHZ(350))
 		e4k_band_set(e4k, E4K_BAND_VHF3);
 	else if (e4k->vco.flo < MHZ(1000))
 		e4k_band_set(e4k, E4K_BAND_UHF);
 	else
 		e4k_band_set(e4k, E4K_BAND_L);
 	/* select and set proper RF filter */
 	e4k_rf_filter_set(e4k);
 	return e4k->vco.flo;
 }
 /*! \brief High-level tuning API, just specify frquency
 *
 *  This function will compute matching PLL parameters, program them into the
 *  hardware and set the band as well as RF filter.
 *
 *  \param[in] e4k reference to tuner
 *  \param[in] freq frequency in Hz
 *  \returns actual tuned frequency, negative in case of error
 */
 int e4k_tune_freq(struct e4k_state *e4k, uint32_t freq)
 {
 	int rc, i;
 	struct e4k_pll_params p;
 	/* determine PLL parameters */
 	rc = e4k_compute_pll_params(&p, e4k->vco.fosc, freq);
 	if (rc < 0)
 		return rc;
 	/* actually tune to those parameters */
 	rc = e4k_tune_params(e4k, &p);
 	/* check PLL lock */
 	rc = e4k_reg_read(e4k, E4K_REG_SYNTH1);
 	if (!(rc & 0x01)) {
 		printf("[E4K] PLL not locked!\n");
 		return -1;
 	}
 	return 0;
 }
 /***********************************************************************
 * Gain Control */
 static const int8_t if_stage1_gain[] = {
 	-3, 6
 };
 static const int8_t if_stage23_gain[] = {
 	0, 3, 6, 9
 };
 static const int8_t if_stage4_gain[] = {
 	0, 1, 2, 2
 };
 static const int8_t if_stage56_gain[] = {
 	3, 6, 9, 12, 15, 15, 15, 15
 };
 static const int8_t *if_stage_gain[] = {
 	0,
 	if_stage1_gain,
 	if_stage23_gain,
 	if_stage23_gain,
 	if_stage4_gain,
 	if_stage56_gain,
 	if_stage56_gain
 };
 static const uint8_t if_stage_gain_len[] = {
 	0,
 	ARRAY_SIZE(if_stage1_gain),
 	ARRAY_SIZE(if_stage23_gain),
 	ARRAY_SIZE(if_stage23_gain),
 	ARRAY_SIZE(if_stage4_gain),
 	ARRAY_SIZE(if_stage56_gain),
 	ARRAY_SIZE(if_stage56_gain)
 };
 static const struct reg_field if_stage_gain_regs[] = {
 	{ E4K_REG_GAIN3, 0, 1 },
 	{ E4K_REG_GAIN3, 1, 2 },
 	{ E4K_REG_GAIN3, 3, 2 },
 	{ E4K_REG_GAIN3, 5, 2 },
 	{ E4K_REG_GAIN4, 0, 3 },
 	{ E4K_REG_GAIN4, 3, 3 }
 };
 static const int32_t lnagain[] = {
 	-50,	0,
 	-25,	1,
 	0,	4,
 	25,	5,
 	50,	6,
 	75,	7,
 	100,	8,
 	125,	9,
 	150,	10,
 	175,	11,
 	200,	12,
 	250,	13,
 	300,	14,
 };
 static const int32_t enhgain[] = {
 	10, 30, 50, 70
 };
 int e4k_set_lna_gain(struct e4k_state *e4k, int32_t gain)
 {
 	uint32_t i;
 	for(i = 0; i < ARRAY_SIZE(lnagain)/2; ++i) {
 		if(lnagain[i*2] == gain) {
 			e4k_reg_set_mask(e4k, E4K_REG_GAIN1, 0xf, lnagain[i*2+1]);
 			return gain;
 		}
 	}
 	return -EINVAL;
 }
 int e4k_set_enh_gain(struct e4k_state *e4k, int32_t gain)
 {
 	uint32_t i;
 	for(i = 0; i < ARRAY_SIZE(enhgain); ++i) {
 		if(enhgain[i] == gain) {
 			e4k_reg_set_mask(e4k, E4K_REG_AGC11, 0x7, E4K_AGC11_LNA_GAIN_ENH | (i << 1));
 			return gain;
 		}
 	}
 	e4k_reg_set_mask(e4k, E4K_REG_AGC11, 0x7, 0);
 	return 0;
 }
 int e4k_enable_manual_gain(struct e4k_state *e4k, uint8_t manual)
 {
 	if (manual) {
 		/* Set LNA mode to manual */
 		e4k_reg_set_mask(e4k, E4K_REG_AGC1, E4K_AGC1_MOD_MASK, E4K_AGC_MOD_SERIAL);
 		/* Set Mixer Gain Control to manual */
 		e4k_reg_set_mask(e4k, E4K_REG_AGC7, E4K_AGC7_MIX_GAIN_AUTO, 0);
 	} else {
 		/* Set LNA mode to auto */
 		e4k_reg_set_mask(e4k, E4K_REG_AGC1, E4K_AGC1_MOD_MASK, E4K_AGC_MOD_IF_SERIAL_LNA_AUTON);
 		/* Set Mixer Gain Control to auto */
 		e4k_reg_set_mask(e4k, E4K_REG_AGC7, E4K_AGC7_MIX_GAIN_AUTO, 1);
 		e4k_reg_set_mask(e4k, E4K_REG_AGC11, 0x7, 0);
 	}
 	return 0;
 }
 static int find_stage_gain(uint8_t stage, int8_t val)
 {
 	const int8_t *arr;
 	int i;
 	if (stage >= ARRAY_SIZE(if_stage_gain))
 		return -EINVAL;
 	arr = if_stage_gain[stage];
 	for (i = 0; i < if_stage_gain_len[stage]; i++) {
 		if (arr[i] == val)
 			return i;
 	}
 	return -EINVAL;
 }
 /*! \brief Set the gain of one of the IF gain stages
 *  \param[e4k] handle to the tuner chip
 *  \param [stage] numbere of the stage (1..6)
 *  \param [value] gain value in dBm
 *  \returns 0 on success, negative in case of error
 */
 int e4k_if_gain_set(struct e4k_state *e4k, uint8_t stage, int8_t value)
 {
 	int rc;
 	uint8_t mask;
 	const struct reg_field *field;
 	rc = find_stage_gain(stage, value);
 	if (rc < 0)
 		return rc;
 	/* compute the bit-mask for the given gain field */
 	field = &if_stage_gain_regs[stage];
 	mask = width2mask[field->width] << field->shift;
 	return e4k_reg_set_mask(e4k, field->reg, mask, rc << field->shift);
 }
 int e4k_mixer_gain_set(struct e4k_state *e4k, int8_t value)
 {
 	uint8_t bit;
 	switch (value) {
 	case 4:
 		bit = 0;
 		break;
 	case 12:
 		bit = 1;
 		break;
 	default:
 		return -EINVAL;
 	}
 	return e4k_reg_set_mask(e4k, E4K_REG_GAIN2, 1, bit);
 }
 int e4k_commonmode_set(struct e4k_state *e4k, int8_t value)
 {
 	if(value < 0)
 		return -EINVAL;
 	else if(value > 7)
 		return -EINVAL;
 	return e4k_reg_set_mask(e4k, E4K_REG_DC7, 7, value);
 }
 /***********************************************************************
 * DC Offset */
 int e4k_manual_dc_offset(struct e4k_state *e4k, int8_t iofs, int8_t irange, int8_t qofs, int8_t qrange)
 {
 	int res;
 	if((iofs < 0x00) || (iofs > 0x3f))
 		return -EINVAL;
 	if((irange < 0x00) || (irange > 0x03))
 		return -EINVAL;
 	if((qofs < 0x00) || (qofs > 0x3f))
 		return -EINVAL;
 	if((qrange < 0x00) || (qrange > 0x03))
 		return -EINVAL;
 	res = e4k_reg_set_mask(e4k, E4K_REG_DC2, 0x3f, iofs);
 	if(res < 0)
 		return res;
 	res = e4k_reg_set_mask(e4k, E4K_REG_DC3, 0x3f, qofs);
 	if(res < 0)
 		return res;
 	res = e4k_reg_set_mask(e4k, E4K_REG_DC4, 0x33, (qrange << 4) | irange);
 	return res;
 }
 /*! \brief Perform a DC offset calibration right now
 *  \param[e4k] handle to the tuner chip
 */
 int e4k_dc_offset_calibrate(struct e4k_state *e4k)
 {
 	/* make sure the DC range detector is enabled */
 	e4k_reg_set_mask(e4k, E4K_REG_DC5, E4K_DC5_RANGE_DET_EN, E4K_DC5_RANGE_DET_EN);
 	return e4k_reg_write(e4k, E4K_REG_DC1, 0x01);
 }
 static const int8_t if_gains_max[] = {
 	0, 6, 9, 9, 2, 15, 15
 };
 struct gain_comb {
 	int8_t mixer_gain;
 	int8_t if1_gain;
 	uint8_t reg;
 };
 static const struct gain_comb dc_gain_comb[] = {
 	{ 4,  -3, 0x50 },
 	{ 4,   6, 0x51 },
 	{ 12, -3, 0x52 },
 	{ 12,  6, 0x53 },
 };
 #define TO_LUT(offset, range)	(offset | (range << 6))
 int e4k_dc_offset_gen_table(struct e4k_state *e4k)
 {
 	uint32_t i;
 	/* FIXME: read ont current gain values and write them back
 	 * before returning to the caller */
 	/* disable auto mixer gain */
 	e4k_reg_set_mask(e4k, E4K_REG_AGC7, E4K_AGC7_MIX_GAIN_AUTO, 0);
 	/* set LNA/IF gain to full manual */
 	e4k_reg_set_mask(e4k, E4K_REG_AGC1, E4K_AGC1_MOD_MASK,
 			 E4K_AGC_MOD_SERIAL);
 	/* set all 'other' gains to maximum */
 	for (i = 2; i <= 6; i++)
 		e4k_if_gain_set(e4k, i, if_gains_max[i]);
 	/* iterate over all mixer + if_stage_1 gain combinations */
 	for (i = 0; i < ARRAY_SIZE(dc_gain_comb); i++) {
 		uint8_t offs_i, offs_q, range, range_i, range_q;
 		/* set the combination of mixer / if1 gain */
 		e4k_mixer_gain_set(e4k, dc_gain_comb[i].mixer_gain);
 		e4k_if_gain_set(e4k, 1, dc_gain_comb[i].if1_gain);
 		/* perform actual calibration */
 		e4k_dc_offset_calibrate(e4k);
 		/* extract I/Q offset and range values */
 		offs_i = e4k_reg_read(e4k, E4K_REG_DC2) & 0x3f;
 		offs_q = e4k_reg_read(e4k, E4K_REG_DC3) & 0x3f;
 		range  = e4k_reg_read(e4k, E4K_REG_DC4);
 		range_i = range & 0x3;
 		range_q = (range >> 4) & 0x3;
 		printf("Table %u I=%u/%u, Q=%u/%u\n",
 			i, range_i, offs_i, range_q, offs_q);
 		/* write into the table */
 		e4k_reg_write(e4k, dc_gain_comb[i].reg,
 			      TO_LUT(offs_q, range_q));
 		e4k_reg_write(e4k, dc_gain_comb[i].reg + 0x10,
 			      TO_LUT(offs_i, range_i));
 	}
 	return 0;
 }
 /***********************************************************************
 * Initialization */
 static int magic_init(struct e4k_state *e4k)
 {
 	e4k_reg_write(e4k, 0x7e, 0x01);
 	e4k_reg_write(e4k, 0x7f, 0xfe);
 	e4k_reg_write(e4k, 0x82, 0x00);
 	e4k_reg_write(e4k, 0x86, 0x50);	/* polarity A */
 	e4k_reg_write(e4k, 0x87, 0x20);
 	e4k_reg_write(e4k, 0x88, 0x01);
 	e4k_reg_write(e4k, 0x9f, 0x7f);
 	e4k_reg_write(e4k, 0xa0, 0x07);
 	return 0;
 }
 /*! \brief Initialize the E4K tuner
 */
 int e4k_init(struct e4k_state *e4k)
 {
 	/* make a dummy i2c read or write command, will not be ACKed! */
 	e4k_reg_read(e4k, 0);
 	/* Make sure we reset everything and clear POR indicator */
 	e4k_reg_write(e4k, E4K_REG_MASTER1,
 		E4K_MASTER1_RESET |
 		E4K_MASTER1_NORM_STBY |
 		E4K_MASTER1_POR_DET
 	);
 	/* Configure clock input */
 	e4k_reg_write(e4k, E4K_REG_CLK_INP, 0x00);
 	/* Disable clock output */
 	e4k_reg_write(e4k, E4K_REG_REF_CLK, 0x00);
 	e4k_reg_write(e4k, E4K_REG_CLKOUT_PWDN, 0x96);
 	/* Write some magic values into registers */
 	magic_init(e4k);
 #if 0
 	/* Set common mode voltage a bit higher for more margin 850 mv */
 	e4k_commonmode_set(e4k, 4);
 	/* Initialize DC offset lookup tables */
 	e4k_dc_offset_gen_table(e4k);
 	/* Enable time variant DC correction */
 	e4k_reg_write(e4k, E4K_REG_DCTIME1, 0x01);
 	e4k_reg_write(e4k, E4K_REG_DCTIME2, 0x01);
 #endif
 	/* Set LNA mode to manual */
 	e4k_reg_write(e4k, E4K_REG_AGC4, 0x10); /* High threshold */
 	e4k_reg_write(e4k, E4K_REG_AGC5, 0x04);	/* Low threshold */
 	e4k_reg_write(e4k, E4K_REG_AGC6, 0x1a);	/* LNA calib + loop rate */
 	e4k_reg_set_mask(e4k, E4K_REG_AGC1, E4K_AGC1_MOD_MASK,
 		E4K_AGC_MOD_SERIAL);
 	/* Set Mixer Gain Control to manual */
 	e4k_reg_set_mask(e4k, E4K_REG_AGC7, E4K_AGC7_MIX_GAIN_AUTO, 0);
 #if 0
 	/* Enable LNA Gain enhancement */
 	e4k_reg_set_mask(e4k, E4K_REG_AGC11, 0x7,
 			 E4K_AGC11_LNA_GAIN_ENH | (2 << 1));
 	/* Enable automatic IF gain mode switching */
 	e4k_reg_set_mask(e4k, E4K_REG_AGC8, 0x1, E4K_AGC8_SENS_LIN_AUTO);
 #endif
 	/* Use auto-gain as default */
 	e4k_enable_manual_gain(e4k, 0);
 	/* Select moderate gain levels */
 	e4k_if_gain_set(e4k, 1, 6);
 	e4k_if_gain_set(e4k, 2, 0);
 	e4k_if_gain_set(e4k, 3, 0);
 	e4k_if_gain_set(e4k, 4, 0);
 	e4k_if_gain_set(e4k, 5, 9);
 	e4k_if_gain_set(e4k, 6, 9);
 	/* Set the most narrow filter we can possibly use */
 	e4k_if_filter_bw_set(e4k, E4K_IF_FILTER_MIX, KHZ(1900));
 	e4k_if_filter_bw_set(e4k, E4K_IF_FILTER_RC, KHZ(1000));
 	e4k_if_filter_bw_set(e4k, E4K_IF_FILTER_CHAN, KHZ(2150));
 	e4k_if_filter_chan_enable(e4k, 1);
 	/* Disable time variant DC correction and LUT */
 	e4k_reg_set_mask(e4k, E4K_REG_DC5, 0x03, 0);
 	e4k_reg_set_mask(e4k, E4K_REG_DCTIME1, 0x03, 0);
 	e4k_reg_set_mask(e4k, E4K_REG_DCTIME2, 0x03, 0);
 	return 0;
 }