/* MaxLinear MXL5005S VSB/QAM/DVBT tuner driver Copyright (C) 2008 MaxLinear Copyright (C) 2006 Steven Toth Functions: mxl5005s_reset() mxl5005s_writereg() mxl5005s_writeregs() mxl5005s_init() mxl5005s_reconfigure() mxl5005s_AssignTunerMode() mxl5005s_set_params() mxl5005s_get_frequency() mxl5005s_get_bandwidth() mxl5005s_release() mxl5005s_attach() Copyright (c) 2008 Realtek Copyright (c) 2008 Jan Hoogenraad, Barnaby Shearer, Andy Hasper Functions: mxl5005s_SetRfFreqHz() 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 2 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, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ /* History of this driver (Steven Toth): I was given a public release of a linux driver that included support for the MaxLinear MXL5005S silicon tuner. Analysis of the tuner driver showed clearly three things. 1. The tuner driver didn't support the LinuxTV tuner API so the code Realtek added had to be removed. 2. A significant amount of the driver is reference driver code from MaxLinear, I felt it was important to identify and preserve this. 3. New code has to be added to interface correctly with the LinuxTV API, as a regular kernel module. Other than the reference driver enum's, I've clearly marked sections of the code and retained the copyright of the respective owners. */ #include #include #include #include #include #include #include "dvb_frontend.h" #include "mxl5005s.h" static int debug = 2; #define dprintk(level, arg...) do { \ if (level <= debug) \ printk(arg); \ } while (0) #define TUNER_REGS_NUM 104 #define INITCTRL_NUM 40 #ifdef _MXL_PRODUCTION #define CHCTRL_NUM 39 #else #define CHCTRL_NUM 36 #endif #define MXLCTRL_NUM 189 #define MASTER_CONTROL_ADDR 9 /* Enumeration of Master Control Register State */ typedef enum { MC_LOAD_START = 1, MC_POWER_DOWN, MC_SYNTH_RESET, MC_SEQ_OFF } Master_Control_State; /* Enumeration of MXL5005 Tuner Modulation Type */ typedef enum { MXL_DEFAULT_MODULATION = 0, MXL_DVBT, MXL_ATSC, MXL_QAM, MXL_ANALOG_CABLE, MXL_ANALOG_OTA } Tuner_Modu_Type; /* MXL5005 Tuner Register Struct */ typedef struct _TunerReg_struct { u16 Reg_Num; /* Tuner Register Address */ u16 Reg_Val; /* Current sofware programmed value waiting to be writen */ } TunerReg_struct; typedef enum { /* Initialization Control Names */ DN_IQTN_AMP_CUT = 1, /* 1 */ BB_MODE, /* 2 */ BB_BUF, /* 3 */ BB_BUF_OA, /* 4 */ BB_ALPF_BANDSELECT, /* 5 */ BB_IQSWAP, /* 6 */ BB_DLPF_BANDSEL, /* 7 */ RFSYN_CHP_GAIN, /* 8 */ RFSYN_EN_CHP_HIGAIN, /* 9 */ AGC_IF, /* 10 */ AGC_RF, /* 11 */ IF_DIVVAL, /* 12 */ IF_VCO_BIAS, /* 13 */ CHCAL_INT_MOD_IF, /* 14 */ CHCAL_FRAC_MOD_IF, /* 15 */ DRV_RES_SEL, /* 16 */ I_DRIVER, /* 17 */ EN_AAF, /* 18 */ EN_3P, /* 19 */ EN_AUX_3P, /* 20 */ SEL_AAF_BAND, /* 21 */ SEQ_ENCLK16_CLK_OUT, /* 22 */ SEQ_SEL4_16B, /* 23 */ XTAL_CAPSELECT, /* 24 */ IF_SEL_DBL, /* 25 */ RFSYN_R_DIV, /* 26 */ SEQ_EXTSYNTHCALIF, /* 27 */ SEQ_EXTDCCAL, /* 28 */ AGC_EN_RSSI, /* 29 */ RFA_ENCLKRFAGC, /* 30 */ RFA_RSSI_REFH, /* 31 */ RFA_RSSI_REF, /* 32 */ RFA_RSSI_REFL, /* 33 */ RFA_FLR, /* 34 */ RFA_CEIL, /* 35 */ SEQ_EXTIQFSMPULSE, /* 36 */ OVERRIDE_1, /* 37 */ BB_INITSTATE_DLPF_TUNE, /* 38 */ TG_R_DIV, /* 39 */ EN_CHP_LIN_B, /* 40 */ /* Channel Change Control Names */ DN_POLY = 51, /* 51 */ DN_RFGAIN, /* 52 */ DN_CAP_RFLPF, /* 53 */ DN_EN_VHFUHFBAR, /* 54 */ DN_GAIN_ADJUST, /* 55 */ DN_IQTNBUF_AMP, /* 56 */ DN_IQTNGNBFBIAS_BST, /* 57 */ RFSYN_EN_OUTMUX, /* 58 */ RFSYN_SEL_VCO_OUT, /* 59 */ RFSYN_SEL_VCO_HI, /* 60 */ RFSYN_SEL_DIVM, /* 61 */ RFSYN_RF_DIV_BIAS, /* 62 */ DN_SEL_FREQ, /* 63 */ RFSYN_VCO_BIAS, /* 64 */ CHCAL_INT_MOD_RF, /* 65 */ CHCAL_FRAC_MOD_RF, /* 66 */ RFSYN_LPF_R, /* 67 */ CHCAL_EN_INT_RF, /* 68 */ TG_LO_DIVVAL, /* 69 */ TG_LO_SELVAL, /* 70 */ TG_DIV_VAL, /* 71 */ TG_VCO_BIAS, /* 72 */ SEQ_EXTPOWERUP, /* 73 */ OVERRIDE_2, /* 74 */ OVERRIDE_3, /* 75 */ OVERRIDE_4, /* 76 */ SEQ_FSM_PULSE, /* 77 */ GPIO_4B, /* 78 */ GPIO_3B, /* 79 */ GPIO_4, /* 80 */ GPIO_3, /* 81 */ GPIO_1B, /* 82 */ DAC_A_ENABLE, /* 83 */ DAC_B_ENABLE, /* 84 */ DAC_DIN_A, /* 85 */ DAC_DIN_B, /* 86 */ #ifdef _MXL_PRODUCTION RFSYN_EN_DIV, /* 87 */ RFSYN_DIVM, /* 88 */ DN_BYPASS_AGC_I2C /* 89 */ #endif } MXL5005_ControlName; /* * The following context is source code provided by MaxLinear. * MaxLinear source code - Common_MXL.h (?) */ /* Constants */ #define MXL5005S_REG_WRITING_TABLE_LEN_MAX 104 #define MXL5005S_LATCH_BYTE 0xfe /* Register address, MSB, and LSB */ #define MXL5005S_BB_IQSWAP_ADDR 59 #define MXL5005S_BB_IQSWAP_MSB 0 #define MXL5005S_BB_IQSWAP_LSB 0 #define MXL5005S_BB_DLPF_BANDSEL_ADDR 53 #define MXL5005S_BB_DLPF_BANDSEL_MSB 4 #define MXL5005S_BB_DLPF_BANDSEL_LSB 3 /* Standard modes */ enum { MXL5005S_STANDARD_DVBT, MXL5005S_STANDARD_ATSC, }; #define MXL5005S_STANDARD_MODE_NUM 2 /* Bandwidth modes */ enum { MXL5005S_BANDWIDTH_6MHZ = 6000000, MXL5005S_BANDWIDTH_7MHZ = 7000000, MXL5005S_BANDWIDTH_8MHZ = 8000000, }; #define MXL5005S_BANDWIDTH_MODE_NUM 3 /* MXL5005 Tuner Control Struct */ typedef struct _TunerControl_struct { u16 Ctrl_Num; /* Control Number */ u16 size; /* Number of bits to represent Value */ u16 addr[25]; /* Array of Tuner Register Address for each bit position */ u16 bit[25]; /* Array of bit position in Register Address for each bit position */ u16 val[25]; /* Binary representation of Value */ } TunerControl_struct; /* MXL5005 Tuner Struct */ struct mxl5005s_state { u8 Mode; /* 0: Analog Mode ; 1: Digital Mode */ u8 IF_Mode; /* for Analog Mode, 0: zero IF; 1: low IF */ u32 Chan_Bandwidth; /* filter channel bandwidth (6, 7, 8) */ u32 IF_OUT; /* Desired IF Out Frequency */ u16 IF_OUT_LOAD; /* IF Out Load Resistor (200/300 Ohms) */ u32 RF_IN; /* RF Input Frequency */ u32 Fxtal; /* XTAL Frequency */ u8 AGC_Mode; /* AGC Mode 0: Dual AGC; 1: Single AGC */ u16 TOP; /* Value: take over point */ u8 CLOCK_OUT; /* 0: turn off clock out; 1: turn on clock out */ u8 DIV_OUT; /* 4MHz or 16MHz */ u8 CAPSELECT; /* 0: disable On-Chip pulling cap; 1: enable */ u8 EN_RSSI; /* 0: disable RSSI; 1: enable RSSI */ u8 Mod_Type; /* Modulation Type; */ /* 0 - Default; 1 - DVB-T; 2 - ATSC; 3 - QAM; 4 - Analog Cable */ u8 TF_Type; /* Tracking Filter Type */ /* 0 - Default; 1 - Off; 2 - Type C; 3 - Type C-H */ /* Calculated Settings */ u32 RF_LO; /* Synth RF LO Frequency */ u32 IF_LO; /* Synth IF LO Frequency */ u32 TG_LO; /* Synth TG_LO Frequency */ /* Pointers to ControlName Arrays */ u16 Init_Ctrl_Num; /* Number of INIT Control Names */ TunerControl_struct Init_Ctrl[INITCTRL_NUM]; /* INIT Control Names Array Pointer */ u16 CH_Ctrl_Num; /* Number of CH Control Names */ TunerControl_struct CH_Ctrl[CHCTRL_NUM]; /* CH Control Name Array Pointer */ u16 MXL_Ctrl_Num; /* Number of MXL Control Names */ TunerControl_struct MXL_Ctrl[MXLCTRL_NUM]; /* MXL Control Name Array Pointer */ /* Pointer to Tuner Register Array */ u16 TunerRegs_Num; /* Number of Tuner Registers */ TunerReg_struct TunerRegs[TUNER_REGS_NUM]; /* Tuner Register Array Pointer */ /* Linux driver framework specific */ struct mxl5005s_config *config; struct dvb_frontend *frontend; struct i2c_adapter *i2c; /* Cache values */ u32 current_mode; }; u16 MXL_ControlWrite(struct dvb_frontend *fe, u16 ControlNum, u32 value); u16 MXL_ControlRead(struct dvb_frontend *fe, u16 controlNum, u32 *value); u16 MXL_GetMasterControl(u8 *MasterReg, int state); void MXL_RegWriteBit(struct dvb_frontend *fe, u8 address, u8 bit, u8 bitVal); u16 MXL_GetCHRegister(struct dvb_frontend *fe, u8 *RegNum, u8 *RegVal, int *count); u32 MXL_Ceiling(u32 value, u32 resolution); u16 MXL_RegRead(struct dvb_frontend *fe, u8 RegNum, u8 *RegVal); u16 MXL_RegWrite(struct dvb_frontend *fe, u8 RegNum, u8 RegVal); u16 MXL_ControlWrite_Group(struct dvb_frontend *fe, u16 controlNum, u32 value, u16 controlGroup); u16 MXL_SetGPIO(struct dvb_frontend *fe, u8 GPIO_Num, u8 GPIO_Val); u16 MXL_GetInitRegister(struct dvb_frontend *fe, u8 * RegNum, u8 *RegVal, int *count); u32 MXL_GetXtalInt(u32 Xtal_Freq); u16 MXL_TuneRF(struct dvb_frontend *fe, u32 RF_Freq); void MXL_SynthIFLO_Calc(struct dvb_frontend *fe); void MXL_SynthRFTGLO_Calc(struct dvb_frontend *fe); u16 MXL_GetCHRegister_ZeroIF(struct dvb_frontend *fe, u8 *RegNum, u8 *RegVal, int *count); int mxl5005s_writeregs(struct dvb_frontend *fe, u8 *addrtable, u8 *datatable, u8 len); u16 MXL_IFSynthInit(struct dvb_frontend *fe); int mxl5005s_AssignTunerMode(struct dvb_frontend *fe, u32 mod_type, u32 bandwidth); int mxl5005s_reconfigure(struct dvb_frontend *fe, u32 mod_type, u32 bandwidth); /* ---------------------------------------------------------------- * Begin: Custom code salvaged from the Realtek driver. * Copyright (c) 2008 Realtek * Copyright (c) 2008 Jan Hoogenraad, Barnaby Shearer, Andy Hasper * This code is placed under the terms of the GNU General Public License * * Released by Realtek under GPLv2. * Thanks to Realtek for a lot of support we received ! * * Revision: 080314 - original version */ int mxl5005s_SetRfFreqHz(struct dvb_frontend *fe, unsigned long RfFreqHz) { struct mxl5005s_state *state = fe->tuner_priv; unsigned char AddrTable[MXL5005S_REG_WRITING_TABLE_LEN_MAX]; unsigned char ByteTable[MXL5005S_REG_WRITING_TABLE_LEN_MAX]; int TableLen; u32 IfDivval; unsigned char MasterControlByte; dprintk(1, "%s() freq=%ld\n", __func__, RfFreqHz); // Set MxL5005S tuner RF frequency according to MxL5005S tuner example code. // Tuner RF frequency setting stage 0 MXL_GetMasterControl(ByteTable, MC_SYNTH_RESET) ; AddrTable[0] = MASTER_CONTROL_ADDR; ByteTable[0] |= state->config->AgcMasterByte; mxl5005s_writeregs(fe, AddrTable, ByteTable, 1); // Tuner RF frequency setting stage 1 MXL_TuneRF(fe, RfFreqHz); MXL_ControlRead(fe, IF_DIVVAL, &IfDivval); MXL_ControlWrite(fe, SEQ_FSM_PULSE, 0); MXL_ControlWrite(fe, SEQ_EXTPOWERUP, 1); MXL_ControlWrite(fe, IF_DIVVAL, 8); MXL_GetCHRegister(fe, AddrTable, ByteTable, &TableLen) ; MXL_GetMasterControl(&MasterControlByte, MC_LOAD_START) ; AddrTable[TableLen] = MASTER_CONTROL_ADDR ; ByteTable[TableLen] = MasterControlByte | state->config->AgcMasterByte; TableLen += 1; mxl5005s_writeregs(fe, AddrTable, ByteTable, TableLen); // Wait 30 ms. msleep(150); // Tuner RF frequency setting stage 2 MXL_ControlWrite(fe, SEQ_FSM_PULSE, 1) ; MXL_ControlWrite(fe, IF_DIVVAL, IfDivval) ; MXL_GetCHRegister_ZeroIF(fe, AddrTable, ByteTable, &TableLen) ; MXL_GetMasterControl(&MasterControlByte, MC_LOAD_START) ; AddrTable[TableLen] = MASTER_CONTROL_ADDR ; ByteTable[TableLen] = MasterControlByte | state->config->AgcMasterByte ; TableLen += 1; mxl5005s_writeregs(fe, AddrTable, ByteTable, TableLen); msleep(100); return 0; } /* End: Custom code taken from the Realtek driver */ /* ---------------------------------------------------------------- * Begin: Reference driver code found in the Realtek driver. * Copyright (c) 2008 MaxLinear */ u16 MXL5005_RegisterInit(struct dvb_frontend *fe) { struct mxl5005s_state *state = fe->tuner_priv; state->TunerRegs_Num = TUNER_REGS_NUM ; // state->TunerRegs = (TunerReg_struct *) calloc( TUNER_REGS_NUM, sizeof(TunerReg_struct) ) ; state->TunerRegs[0].Reg_Num = 9 ; state->TunerRegs[0].Reg_Val = 0x40 ; state->TunerRegs[1].Reg_Num = 11 ; state->TunerRegs[1].Reg_Val = 0x19 ; state->TunerRegs[2].Reg_Num = 12 ; state->TunerRegs[2].Reg_Val = 0x60 ; state->TunerRegs[3].Reg_Num = 13 ; state->TunerRegs[3].Reg_Val = 0x00 ; state->TunerRegs[4].Reg_Num = 14 ; state->TunerRegs[4].Reg_Val = 0x00 ; state->TunerRegs[5].Reg_Num = 15 ; state->TunerRegs[5].Reg_Val = 0xC0 ; state->TunerRegs[6].Reg_Num = 16 ; state->TunerRegs[6].Reg_Val = 0x00 ; state->TunerRegs[7].Reg_Num = 17 ; state->TunerRegs[7].Reg_Val = 0x00 ; state->TunerRegs[8].Reg_Num = 18 ; state->TunerRegs[8].Reg_Val = 0x00 ; state->TunerRegs[9].Reg_Num = 19 ; state->TunerRegs[9].Reg_Val = 0x34 ; state->TunerRegs[10].Reg_Num = 21 ; state->TunerRegs[10].Reg_Val = 0x00 ; state->TunerRegs[11].Reg_Num = 22 ; state->TunerRegs[11].Reg_Val = 0x6B ; state->TunerRegs[12].Reg_Num = 23 ; state->TunerRegs[12].Reg_Val = 0x35 ; state->TunerRegs[13].Reg_Num = 24 ; state->TunerRegs[13].Reg_Val = 0x70 ; state->TunerRegs[14].Reg_Num = 25 ; state->TunerRegs[14].Reg_Val = 0x3E ; state->TunerRegs[15].Reg_Num = 26 ; state->TunerRegs[15].Reg_Val = 0x82 ; state->TunerRegs[16].Reg_Num = 31 ; state->TunerRegs[16].Reg_Val = 0x00 ; state->TunerRegs[17].Reg_Num = 32 ; state->TunerRegs[17].Reg_Val = 0x40 ; state->TunerRegs[18].Reg_Num = 33 ; state->TunerRegs[18].Reg_Val = 0x53 ; state->TunerRegs[19].Reg_Num = 34 ; state->TunerRegs[19].Reg_Val = 0x81 ; state->TunerRegs[20].Reg_Num = 35 ; state->TunerRegs[20].Reg_Val = 0xC9 ; state->TunerRegs[21].Reg_Num = 36 ; state->TunerRegs[21].Reg_Val = 0x01 ; state->TunerRegs[22].Reg_Num = 37 ; state->TunerRegs[22].Reg_Val = 0x00 ; state->TunerRegs[23].Reg_Num = 41 ; state->TunerRegs[23].Reg_Val = 0x00 ; state->TunerRegs[24].Reg_Num = 42 ; state->TunerRegs[24].Reg_Val = 0xF8 ; state->TunerRegs[25].Reg_Num = 43 ; state->TunerRegs[25].Reg_Val = 0x43 ; state->TunerRegs[26].Reg_Num = 44 ; state->TunerRegs[26].Reg_Val = 0x20 ; state->TunerRegs[27].Reg_Num = 45 ; state->TunerRegs[27].Reg_Val = 0x80 ; state->TunerRegs[28].Reg_Num = 46 ; state->TunerRegs[28].Reg_Val = 0x88 ; state->TunerRegs[29].Reg_Num = 47 ; state->TunerRegs[29].Reg_Val = 0x86 ; state->TunerRegs[30].Reg_Num = 48 ; state->TunerRegs[30].Reg_Val = 0x00 ; state->TunerRegs[31].Reg_Num = 49 ; state->TunerRegs[31].Reg_Val = 0x00 ; state->TunerRegs[32].Reg_Num = 53 ; state->TunerRegs[32].Reg_Val = 0x94 ; state->TunerRegs[33].Reg_Num = 54 ; state->TunerRegs[33].Reg_Val = 0xFA ; state->TunerRegs[34].Reg_Num = 55 ; state->TunerRegs[34].Reg_Val = 0x92 ; state->TunerRegs[35].Reg_Num = 56 ; state->TunerRegs[35].Reg_Val = 0x80 ; state->TunerRegs[36].Reg_Num = 57 ; state->TunerRegs[36].Reg_Val = 0x41 ; state->TunerRegs[37].Reg_Num = 58 ; state->TunerRegs[37].Reg_Val = 0xDB ; state->TunerRegs[38].Reg_Num = 59 ; state->TunerRegs[38].Reg_Val = 0x00 ; state->TunerRegs[39].Reg_Num = 60 ; state->TunerRegs[39].Reg_Val = 0x00 ; state->TunerRegs[40].Reg_Num = 61 ; state->TunerRegs[40].Reg_Val = 0x00 ; state->TunerRegs[41].Reg_Num = 62 ; state->TunerRegs[41].Reg_Val = 0x00 ; state->TunerRegs[42].Reg_Num = 65 ; state->TunerRegs[42].Reg_Val = 0xF8 ; state->TunerRegs[43].Reg_Num = 66 ; state->TunerRegs[43].Reg_Val = 0xE4 ; state->TunerRegs[44].Reg_Num = 67 ; state->TunerRegs[44].Reg_Val = 0x90 ; state->TunerRegs[45].Reg_Num = 68 ; state->TunerRegs[45].Reg_Val = 0xC0 ; state->TunerRegs[46].Reg_Num = 69 ; state->TunerRegs[46].Reg_Val = 0x01 ; state->TunerRegs[47].Reg_Num = 70 ; state->TunerRegs[47].Reg_Val = 0x50 ; state->TunerRegs[48].Reg_Num = 71 ; state->TunerRegs[48].Reg_Val = 0x06 ; state->TunerRegs[49].Reg_Num = 72 ; state->TunerRegs[49].Reg_Val = 0x00 ; state->TunerRegs[50].Reg_Num = 73 ; state->TunerRegs[50].Reg_Val = 0x20 ; state->TunerRegs[51].Reg_Num = 76 ; state->TunerRegs[51].Reg_Val = 0xBB ; state->TunerRegs[52].Reg_Num = 77 ; state->TunerRegs[52].Reg_Val = 0x13 ; state->TunerRegs[53].Reg_Num = 81 ; state->TunerRegs[53].Reg_Val = 0x04 ; state->TunerRegs[54].Reg_Num = 82 ; state->TunerRegs[54].Reg_Val = 0x75 ; state->TunerRegs[55].Reg_Num = 83 ; state->TunerRegs[55].Reg_Val = 0x00 ; state->TunerRegs[56].Reg_Num = 84 ; state->TunerRegs[56].Reg_Val = 0x00 ; state->TunerRegs[57].Reg_Num = 85 ; state->TunerRegs[57].Reg_Val = 0x00 ; state->TunerRegs[58].Reg_Num = 91 ; state->TunerRegs[58].Reg_Val = 0x70 ; state->TunerRegs[59].Reg_Num = 92 ; state->TunerRegs[59].Reg_Val = 0x00 ; state->TunerRegs[60].Reg_Num = 93 ; state->TunerRegs[60].Reg_Val = 0x00 ; state->TunerRegs[61].Reg_Num = 94 ; state->TunerRegs[61].Reg_Val = 0x00 ; state->TunerRegs[62].Reg_Num = 95 ; state->TunerRegs[62].Reg_Val = 0x0C ; state->TunerRegs[63].Reg_Num = 96 ; state->TunerRegs[63].Reg_Val = 0x00 ; state->TunerRegs[64].Reg_Num = 97 ; state->TunerRegs[64].Reg_Val = 0x00 ; state->TunerRegs[65].Reg_Num = 98 ; state->TunerRegs[65].Reg_Val = 0xE2 ; state->TunerRegs[66].Reg_Num = 99 ; state->TunerRegs[66].Reg_Val = 0x00 ; state->TunerRegs[67].Reg_Num = 100 ; state->TunerRegs[67].Reg_Val = 0x00 ; state->TunerRegs[68].Reg_Num = 101 ; state->TunerRegs[68].Reg_Val = 0x12 ; state->TunerRegs[69].Reg_Num = 102 ; state->TunerRegs[69].Reg_Val = 0x80 ; state->TunerRegs[70].Reg_Num = 103 ; state->TunerRegs[70].Reg_Val = 0x32 ; state->TunerRegs[71].Reg_Num = 104 ; state->TunerRegs[71].Reg_Val = 0xB4 ; state->TunerRegs[72].Reg_Num = 105 ; state->TunerRegs[72].Reg_Val = 0x60 ; state->TunerRegs[73].Reg_Num = 106 ; state->TunerRegs[73].Reg_Val = 0x83 ; state->TunerRegs[74].Reg_Num = 107 ; state->TunerRegs[74].Reg_Val = 0x84 ; state->TunerRegs[75].Reg_Num = 108 ; state->TunerRegs[75].Reg_Val = 0x9C ; state->TunerRegs[76].Reg_Num = 109 ; state->TunerRegs[76].Reg_Val = 0x02 ; state->TunerRegs[77].Reg_Num = 110 ; state->TunerRegs[77].Reg_Val = 0x81 ; state->TunerRegs[78].Reg_Num = 111 ; state->TunerRegs[78].Reg_Val = 0xC0 ; state->TunerRegs[79].Reg_Num = 112 ; state->TunerRegs[79].Reg_Val = 0x10 ; state->TunerRegs[80].Reg_Num = 131 ; state->TunerRegs[80].Reg_Val = 0x8A ; state->TunerRegs[81].Reg_Num = 132 ; state->TunerRegs[81].Reg_Val = 0x10 ; state->TunerRegs[82].Reg_Num = 133 ; state->TunerRegs[82].Reg_Val = 0x24 ; state->TunerRegs[83].Reg_Num = 134 ; state->TunerRegs[83].Reg_Val = 0x00 ; state->TunerRegs[84].Reg_Num = 135 ; state->TunerRegs[84].Reg_Val = 0x00 ; state->TunerRegs[85].Reg_Num = 136 ; state->TunerRegs[85].Reg_Val = 0x7E ; state->TunerRegs[86].Reg_Num = 137 ; state->TunerRegs[86].Reg_Val = 0x40 ; state->TunerRegs[87].Reg_Num = 138 ; state->TunerRegs[87].Reg_Val = 0x38 ; state->TunerRegs[88].Reg_Num = 146 ; state->TunerRegs[88].Reg_Val = 0xF6 ; state->TunerRegs[89].Reg_Num = 147 ; state->TunerRegs[89].Reg_Val = 0x1A ; state->TunerRegs[90].Reg_Num = 148 ; state->TunerRegs[90].Reg_Val = 0x62 ; state->TunerRegs[91].Reg_Num = 149 ; state->TunerRegs[91].Reg_Val = 0x33 ; state->TunerRegs[92].Reg_Num = 150 ; state->TunerRegs[92].Reg_Val = 0x80 ; state->TunerRegs[93].Reg_Num = 156 ; state->TunerRegs[93].Reg_Val = 0x56 ; state->TunerRegs[94].Reg_Num = 157 ; state->TunerRegs[94].Reg_Val = 0x17 ; state->TunerRegs[95].Reg_Num = 158 ; state->TunerRegs[95].Reg_Val = 0xA9 ; state->TunerRegs[96].Reg_Num = 159 ; state->TunerRegs[96].Reg_Val = 0x00 ; state->TunerRegs[97].Reg_Num = 160 ; state->TunerRegs[97].Reg_Val = 0x00 ; state->TunerRegs[98].Reg_Num = 161 ; state->TunerRegs[98].Reg_Val = 0x00 ; state->TunerRegs[99].Reg_Num = 162 ; state->TunerRegs[99].Reg_Val = 0x40 ; state->TunerRegs[100].Reg_Num = 166 ; state->TunerRegs[100].Reg_Val = 0xAE ; state->TunerRegs[101].Reg_Num = 167 ; state->TunerRegs[101].Reg_Val = 0x1B ; state->TunerRegs[102].Reg_Num = 168 ; state->TunerRegs[102].Reg_Val = 0xF2 ; state->TunerRegs[103].Reg_Num = 195 ; state->TunerRegs[103].Reg_Val = 0x00 ; return 0 ; } u16 MXL5005_ControlInit(struct dvb_frontend *fe) { struct mxl5005s_state *state = fe->tuner_priv; state->Init_Ctrl_Num = INITCTRL_NUM; state->Init_Ctrl[0].Ctrl_Num = DN_IQTN_AMP_CUT ; state->Init_Ctrl[0].size = 1 ; state->Init_Ctrl[0].addr[0] = 73; state->Init_Ctrl[0].bit[0] = 7; state->Init_Ctrl[0].val[0] = 0; state->Init_Ctrl[1].Ctrl_Num = BB_MODE ; state->Init_Ctrl[1].size = 1 ; state->Init_Ctrl[1].addr[0] = 53; state->Init_Ctrl[1].bit[0] = 2; state->Init_Ctrl[1].val[0] = 1; state->Init_Ctrl[2].Ctrl_Num = BB_BUF ; state->Init_Ctrl[2].size = 2 ; state->Init_Ctrl[2].addr[0] = 53; state->Init_Ctrl[2].bit[0] = 1; state->Init_Ctrl[2].val[0] = 0; state->Init_Ctrl[2].addr[1] = 57; state->Init_Ctrl[2].bit[1] = 0; state->Init_Ctrl[2].val[1] = 1; state->Init_Ctrl[3].Ctrl_Num = BB_BUF_OA ; state->Init_Ctrl[3].size = 1 ; state->Init_Ctrl[3].addr[0] = 53; state->Init_Ctrl[3].bit[0] = 0; state->Init_Ctrl[3].val[0] = 0; state->Init_Ctrl[4].Ctrl_Num = BB_ALPF_BANDSELECT ; state->Init_Ctrl[4].size = 3 ; state->Init_Ctrl[4].addr[0] = 53; state->Init_Ctrl[4].bit[0] = 5; state->Init_Ctrl[4].val[0] = 0; state->Init_Ctrl[4].addr[1] = 53; state->Init_Ctrl[4].bit[1] = 6; state->Init_Ctrl[4].val[1] = 0; state->Init_Ctrl[4].addr[2] = 53; state->Init_Ctrl[4].bit[2] = 7; state->Init_Ctrl[4].val[2] = 1; state->Init_Ctrl[5].Ctrl_Num = BB_IQSWAP ; state->Init_Ctrl[5].size = 1 ; state->Init_Ctrl[5].addr[0] = 59; state->Init_Ctrl[5].bit[0] = 0; state->Init_Ctrl[5].val[0] = 0; state->Init_Ctrl[6].Ctrl_Num = BB_DLPF_BANDSEL ; state->Init_Ctrl[6].size = 2 ; state->Init_Ctrl[6].addr[0] = 53; state->Init_Ctrl[6].bit[0] = 3; state->Init_Ctrl[6].val[0] = 0; state->Init_Ctrl[6].addr[1] = 53; state->Init_Ctrl[6].bit[1] = 4; state->Init_Ctrl[6].val[1] = 1; state->Init_Ctrl[7].Ctrl_Num = RFSYN_CHP_GAIN ; state->Init_Ctrl[7].size = 4 ; state->Init_Ctrl[7].addr[0] = 22; state->Init_Ctrl[7].bit[0] = 4; state->Init_Ctrl[7].val[0] = 0; state->Init_Ctrl[7].addr[1] = 22; state->Init_Ctrl[7].bit[1] = 5; state->Init_Ctrl[7].val[1] = 1; state->Init_Ctrl[7].addr[2] = 22; state->Init_Ctrl[7].bit[2] = 6; state->Init_Ctrl[7].val[2] = 1; state->Init_Ctrl[7].addr[3] = 22; state->Init_Ctrl[7].bit[3] = 7; state->Init_Ctrl[7].val[3] = 0; state->Init_Ctrl[8].Ctrl_Num = RFSYN_EN_CHP_HIGAIN ; state->Init_Ctrl[8].size = 1 ; state->Init_Ctrl[8].addr[0] = 22; state->Init_Ctrl[8].bit[0] = 2; state->Init_Ctrl[8].val[0] = 0; state->Init_Ctrl[9].Ctrl_Num = AGC_IF ; state->Init_Ctrl[9].size = 4 ; state->Init_Ctrl[9].addr[0] = 76; state->Init_Ctrl[9].bit[0] = 0; state->Init_Ctrl[9].val[0] = 1; state->Init_Ctrl[9].addr[1] = 76; state->Init_Ctrl[9].bit[1] = 1; state->Init_Ctrl[9].val[1] = 1; state->Init_Ctrl[9].addr[2] = 76; state->Init_Ctrl[9].bit[2] = 2; state->Init_Ctrl[9].val[2] = 0; state->Init_Ctrl[9].addr[3] = 76; state->Init_Ctrl[9].bit[3] = 3; state->Init_Ctrl[9].val[3] = 1; state->Init_Ctrl[10].Ctrl_Num = AGC_RF ; state->Init_Ctrl[10].size = 4 ; state->Init_Ctrl[10].addr[0] = 76; state->Init_Ctrl[10].bit[0] = 4; state->Init_Ctrl[10].val[0] = 1; state->Init_Ctrl[10].addr[1] = 76; state->Init_Ctrl[10].bit[1] = 5; state->Init_Ctrl[10].val[1] = 1; state->Init_Ctrl[10].addr[2] = 76; state->Init_Ctrl[10].bit[2] = 6; state->Init_Ctrl[10].val[2] = 0; state->Init_Ctrl[10].addr[3] = 76; state->Init_Ctrl[10].bit[3] = 7; state->Init_Ctrl[10].val[3] = 1; state->Init_Ctrl[11].Ctrl_Num = IF_DIVVAL ; state->Init_Ctrl[11].size = 5 ; state->Init_Ctrl[11].addr[0] = 43; state->Init_Ctrl[11].bit[0] = 3; state->Init_Ctrl[11].val[0] = 0; state->Init_Ctrl[11].addr[1] = 43; state->Init_Ctrl[11].bit[1] = 4; state->Init_Ctrl[11].val[1] = 0; state->Init_Ctrl[11].addr[2] = 43; state->Init_Ctrl[11].bit[2] = 5; state->Init_Ctrl[11].val[2] = 0; state->Init_Ctrl[11].addr[3] = 43; state->Init_Ctrl[11].bit[3] = 6; state->Init_Ctrl[11].val[3] = 1; state->Init_Ctrl[11].addr[4] = 43; state->Init_Ctrl[11].bit[4] = 7; state->Init_Ctrl[11].val[4] = 0; state->Init_Ctrl[12].Ctrl_Num = IF_VCO_BIAS ; state->Init_Ctrl[12].size = 6 ; state->Init_Ctrl[12].addr[0] = 44; state->Init_Ctrl[12].bit[0] = 2; state->Init_Ctrl[12].val[0] = 0; state->Init_Ctrl[12].addr[1] = 44; state->Init_Ctrl[12].bit[1] = 3; state->Init_Ctrl[12].val[1] = 0; state->Init_Ctrl[12].addr[2] = 44; state->Init_Ctrl[12].bit[2] = 4; state->Init_Ctrl[12].val[2] = 0; state->Init_Ctrl[12].addr[3] = 44; state->Init_Ctrl[12].bit[3] = 5; state->Init_Ctrl[12].val[3] = 1; state->Init_Ctrl[12].addr[4] = 44; state->Init_Ctrl[12].bit[4] = 6; state->Init_Ctrl[12].val[4] = 0; state->Init_Ctrl[12].addr[5] = 44; state->Init_Ctrl[12].bit[5] = 7; state->Init_Ctrl[12].val[5] = 0; state->Init_Ctrl[13].Ctrl_Num = CHCAL_INT_MOD_IF ; state->Init_Ctrl[13].size = 7 ; state->Init_Ctrl[13].addr[0] = 11; state->Init_Ctrl[13].bit[0] = 0; state->Init_Ctrl[13].val[0] = 1; state->Init_Ctrl[13].addr[1] = 11; state->Init_Ctrl[13].bit[1] = 1; state->Init_Ctrl[13].val[1] = 0; state->Init_Ctrl[13].addr[2] = 11; state->Init_Ctrl[13].bit[2] = 2; state->Init_Ctrl[13].val[2] = 0; state->Init_Ctrl[13].addr[3] = 11; state->Init_Ctrl[13].bit[3] = 3; state->Init_Ctrl[13].val[3] = 1; state->Init_Ctrl[13].addr[4] = 11; state->Init_Ctrl[13].bit[4] = 4; state->Init_Ctrl[13].val[4] = 1; state->Init_Ctrl[13].addr[5] = 11; state->Init_Ctrl[13].bit[5] = 5; state->Init_Ctrl[13].val[5] = 0; state->Init_Ctrl[13].addr[6] = 11; state->Init_Ctrl[13].bit[6] = 6; state->Init_Ctrl[13].val[6] = 0; state->Init_Ctrl[14].Ctrl_Num = CHCAL_FRAC_MOD_IF ; state->Init_Ctrl[14].size = 16 ; state->Init_Ctrl[14].addr[0] = 13; state->Init_Ctrl[14].bit[0] = 0; state->Init_Ctrl[14].val[0] = 0; state->Init_Ctrl[14].addr[1] = 13; state->Init_Ctrl[14].bit[1] = 1; state->Init_Ctrl[14].val[1] = 0; state->Init_Ctrl[14].addr[2] = 13; state->Init_Ctrl[14].bit[2] = 2; state->Init_Ctrl[14].val[2] = 0; state->Init_Ctrl[14].addr[3] = 13; state->Init_Ctrl[14].bit[3] = 3; state->Init_Ctrl[14].val[3] = 0; state->Init_Ctrl[14].addr[4] = 13; state->Init_Ctrl[14].bit[4] = 4; state->Init_Ctrl[14].val[4] = 0; state->Init_Ctrl[14].addr[5] = 13; state->Init_Ctrl[14].bit[5] = 5; state->Init_Ctrl[14].val[5] = 0; state->Init_Ctrl[14].addr[6] = 13; state->Init_Ctrl[14].bit[6] = 6; state->Init_Ctrl[14].val[6] = 0; state->Init_Ctrl[14].addr[7] = 13; state->Init_Ctrl[14].bit[7] = 7; state->Init_Ctrl[14].val[7] = 0; state->Init_Ctrl[14].addr[8] = 12; state->Init_Ctrl[14].bit[8] = 0; state->Init_Ctrl[14].val[8] = 0; state->Init_Ctrl[14].addr[9] = 12; state->Init_Ctrl[14].bit[9] = 1; state->Init_Ctrl[14].val[9] = 0; state->Init_Ctrl[14].addr[10] = 12; state->Init_Ctrl[14].bit[10] = 2; state->Init_Ctrl[14].val[10] = 0; state->Init_Ctrl[14].addr[11] = 12; state->Init_Ctrl[14].bit[11] = 3; state->Init_Ctrl[14].val[11] = 0; state->Init_Ctrl[14].addr[12] = 12; state->Init_Ctrl[14].bit[12] = 4; state->Init_Ctrl[14].val[12] = 0; state->Init_Ctrl[14].addr[13] = 12; state->Init_Ctrl[14].bit[13] = 5; state->Init_Ctrl[14].val[13] = 1; state->Init_Ctrl[14].addr[14] = 12; state->Init_Ctrl[14].bit[14] = 6; state->Init_Ctrl[14].val[14] = 1; state->Init_Ctrl[14].addr[15] = 12; state->Init_Ctrl[14].bit[15] = 7; state->Init_Ctrl[14].val[15] = 0; state->Init_Ctrl[15].Ctrl_Num = DRV_RES_SEL ; state->Init_Ctrl[15].size = 3 ; state->Init_Ctrl[15].addr[0] = 147; state->Init_Ctrl[15].bit[0] = 2; state->Init_Ctrl[15].val[0] = 0; state->Init_Ctrl[15].addr[1] = 147; state->Init_Ctrl[15].bit[1] = 3; state->Init_Ctrl[15].val[1] = 1; state->Init_Ctrl[15].addr[2] = 147; state->Init_Ctrl[15].bit[2] = 4; state->Init_Ctrl[15].val[2] = 1; state->Init_Ctrl[16].Ctrl_Num = I_DRIVER ; state->Init_Ctrl[16].size = 2 ; state->Init_Ctrl[16].addr[0] = 147; state->Init_Ctrl[16].bit[0] = 0; state->Init_Ctrl[16].val[0] = 0; state->Init_Ctrl[16].addr[1] = 147; state->Init_Ctrl[16].bit[1] = 1; state->Init_Ctrl[16].val[1] = 1; state->Init_Ctrl[17].Ctrl_Num = EN_AAF ; state->Init_Ctrl[17].size = 1 ; state->Init_Ctrl[17].addr[0] = 147; state->Init_Ctrl[17].bit[0] = 7; state->Init_Ctrl[17].val[0] = 0; state->Init_Ctrl[18].Ctrl_Num = EN_3P ; state->Init_Ctrl[18].size = 1 ; state->Init_Ctrl[18].addr[0] = 147; state->Init_Ctrl[18].bit[0] = 6; state->Init_Ctrl[18].val[0] = 0; state->Init_Ctrl[19].Ctrl_Num = EN_AUX_3P ; state->Init_Ctrl[19].size = 1 ; state->Init_Ctrl[19].addr[0] = 156; state->Init_Ctrl[19].bit[0] = 0; state->Init_Ctrl[19].val[0] = 0; state->Init_Ctrl[20].Ctrl_Num = SEL_AAF_BAND ; state->Init_Ctrl[20].size = 1 ; state->Init_Ctrl[20].addr[0] = 147; state->Init_Ctrl[20].bit[0] = 5; state->Init_Ctrl[20].val[0] = 0; state->Init_Ctrl[21].Ctrl_Num = SEQ_ENCLK16_CLK_OUT ; state->Init_Ctrl[21].size = 1 ; state->Init_Ctrl[21].addr[0] = 137; state->Init_Ctrl[21].bit[0] = 4; state->Init_Ctrl[21].val[0] = 0; state->Init_Ctrl[22].Ctrl_Num = SEQ_SEL4_16B ; state->Init_Ctrl[22].size = 1 ; state->Init_Ctrl[22].addr[0] = 137; state->Init_Ctrl[22].bit[0] = 7; state->Init_Ctrl[22].val[0] = 0; state->Init_Ctrl[23].Ctrl_Num = XTAL_CAPSELECT ; state->Init_Ctrl[23].size = 1 ; state->Init_Ctrl[23].addr[0] = 91; state->Init_Ctrl[23].bit[0] = 5; state->Init_Ctrl[23].val[0] = 1; state->Init_Ctrl[24].Ctrl_Num = IF_SEL_DBL ; state->Init_Ctrl[24].size = 1 ; state->Init_Ctrl[24].addr[0] = 43; state->Init_Ctrl[24].bit[0] = 0; state->Init_Ctrl[24].val[0] = 1; state->Init_Ctrl[25].Ctrl_Num = RFSYN_R_DIV ; state->Init_Ctrl[25].size = 2 ; state->Init_Ctrl[25].addr[0] = 22; state->Init_Ctrl[25].bit[0] = 0; state->Init_Ctrl[25].val[0] = 1; state->Init_Ctrl[25].addr[1] = 22; state->Init_Ctrl[25].bit[1] = 1; state->Init_Ctrl[25].val[1] = 1; state->Init_Ctrl[26].Ctrl_Num = SEQ_EXTSYNTHCALIF ; state->Init_Ctrl[26].size = 1 ; state->Init_Ctrl[26].addr[0] = 134; state->Init_Ctrl[26].bit[0] = 2; state->Init_Ctrl[26].val[0] = 0; state->Init_Ctrl[27].Ctrl_Num = SEQ_EXTDCCAL ; state->Init_Ctrl[27].size = 1 ; state->Init_Ctrl[27].addr[0] = 137; state->Init_Ctrl[27].bit[0] = 3; state->Init_Ctrl[27].val[0] = 0; state->Init_Ctrl[28].Ctrl_Num = AGC_EN_RSSI ; state->Init_Ctrl[28].size = 1 ; state->Init_Ctrl[28].addr[0] = 77; state->Init_Ctrl[28].bit[0] = 7; state->Init_Ctrl[28].val[0] = 0; state->Init_Ctrl[29].Ctrl_Num = RFA_ENCLKRFAGC ; state->Init_Ctrl[29].size = 1 ; state->Init_Ctrl[29].addr[0] = 166; state->Init_Ctrl[29].bit[0] = 7; state->Init_Ctrl[29].val[0] = 1; state->Init_Ctrl[30].Ctrl_Num = RFA_RSSI_REFH ; state->Init_Ctrl[30].size = 3 ; state->Init_Ctrl[30].addr[0] = 166; state->Init_Ctrl[30].bit[0] = 0; state->Init_Ctrl[30].val[0] = 0; state->Init_Ctrl[30].addr[1] = 166; state->Init_Ctrl[30].bit[1] = 1; state->Init_Ctrl[30].val[1] = 1; state->Init_Ctrl[30].addr[2] = 166; state->Init_Ctrl[30].bit[2] = 2; state->Init_Ctrl[30].val[2] = 1; state->Init_Ctrl[31].Ctrl_Num = RFA_RSSI_REF ; state->Init_Ctrl[31].size = 3 ; state->Init_Ctrl[31].addr[0] = 166; state->Init_Ctrl[31].bit[0] = 3; state->Init_Ctrl[31].val[0] = 1; state->Init_Ctrl[31].addr[1] = 166; state->Init_Ctrl[31].bit[1] = 4; state->Init_Ctrl[31].val[1] = 0; state->Init_Ctrl[31].addr[2] = 166; state->Init_Ctrl[31].bit[2] = 5; state->Init_Ctrl[31].val[2] = 1; state->Init_Ctrl[32].Ctrl_Num = RFA_RSSI_REFL ; state->Init_Ctrl[32].size = 3 ; state->Init_Ctrl[32].addr[0] = 167; state->Init_Ctrl[32].bit[0] = 0; state->Init_Ctrl[32].val[0] = 1; state->Init_Ctrl[32].addr[1] = 167; state->Init_Ctrl[32].bit[1] = 1; state->Init_Ctrl[32].val[1] = 1; state->Init_Ctrl[32].addr[2] = 167; state->Init_Ctrl[32].bit[2] = 2; state->Init_Ctrl[32].val[2] = 0; state->Init_Ctrl[33].Ctrl_Num = RFA_FLR ; state->Init_Ctrl[33].size = 4 ; state->Init_Ctrl[33].addr[0] = 168; state->Init_Ctrl[33].bit[0] = 0; state->Init_Ctrl[33].val[0] = 0; state->Init_Ctrl[33].addr[1] = 168; state->Init_Ctrl[33].bit[1] = 1; state->Init_Ctrl[33].val[1] = 1; state->Init_Ctrl[33].addr[2] = 168; state->Init_Ctrl[33].bit[2] = 2; state->Init_Ctrl[33].val[2] = 0; state->Init_Ctrl[33].addr[3] = 168; state->Init_Ctrl[33].bit[3] = 3; state->Init_Ctrl[33].val[3] = 0; state->Init_Ctrl[34].Ctrl_Num = RFA_CEIL ; state->Init_Ctrl[34].size = 4 ; state->Init_Ctrl[34].addr[0] = 168; state->Init_Ctrl[34].bit[0] = 4; state->Init_Ctrl[34].val[0] = 1; state->Init_Ctrl[34].addr[1] = 168; state->Init_Ctrl[34].bit[1] = 5; state->Init_Ctrl[34].val[1] = 1; state->Init_Ctrl[34].addr[2] = 168; state->Init_Ctrl[34].bit[2] = 6; state->Init_Ctrl[34].val[2] = 1; state->Init_Ctrl[34].addr[3] = 168; state->Init_Ctrl[34].bit[3] = 7; state->Init_Ctrl[34].val[3] = 1; state->Init_Ctrl[35].Ctrl_Num = SEQ_EXTIQFSMPULSE ; state->Init_Ctrl[35].size = 1 ; state->Init_Ctrl[35].addr[0] = 135; state->Init_Ctrl[35].bit[0] = 0; state->Init_Ctrl[35].val[0] = 0; state->Init_Ctrl[36].Ctrl_Num = OVERRIDE_1 ; state->Init_Ctrl[36].size = 1 ; state->Init_Ctrl[36].addr[0] = 56; state->Init_Ctrl[36].bit[0] = 3; state->Init_Ctrl[36].val[0] = 0; state->Init_Ctrl[37].Ctrl_Num = BB_INITSTATE_DLPF_TUNE ; state->Init_Ctrl[37].size = 7 ; state->Init_Ctrl[37].addr[0] = 59; state->Init_Ctrl[37].bit[0] = 1; state->Init_Ctrl[37].val[0] = 0; state->Init_Ctrl[37].addr[1] = 59; state->Init_Ctrl[37].bit[1] = 2; state->Init_Ctrl[37].val[1] = 0; state->Init_Ctrl[37].addr[2] = 59; state->Init_Ctrl[37].bit[2] = 3; state->Init_Ctrl[37].val[2] = 0; state->Init_Ctrl[37].addr[3] = 59; state->Init_Ctrl[37].bit[3] = 4; state->Init_Ctrl[37].val[3] = 0; state->Init_Ctrl[37].addr[4] = 59; state->Init_Ctrl[37].bit[4] = 5; state->Init_Ctrl[37].val[4] = 0; state->Init_Ctrl[37].addr[5] = 59; state->Init_Ctrl[37].bit[5] = 6; state->Init_Ctrl[37].val[5] = 0; state->Init_Ctrl[37].addr[6] = 59; state->Init_Ctrl[37].bit[6] = 7; state->Init_Ctrl[37].val[6] = 0; state->Init_Ctrl[38].Ctrl_Num = TG_R_DIV ; state->Init_Ctrl[38].size = 6 ; state->Init_Ctrl[38].addr[0] = 32; state->Init_Ctrl[38].bit[0] = 2; state->Init_Ctrl[38].val[0] = 0; state->Init_Ctrl[38].addr[1] = 32; state->Init_Ctrl[38].bit[1] = 3; state->Init_Ctrl[38].val[1] = 0; state->Init_Ctrl[38].addr[2] = 32; state->Init_Ctrl[38].bit[2] = 4; state->Init_Ctrl[38].val[2] = 0; state->Init_Ctrl[38].addr[3] = 32; state->Init_Ctrl[38].bit[3] = 5; state->Init_Ctrl[38].val[3] = 0; state->Init_Ctrl[38].addr[4] = 32; state->Init_Ctrl[38].bit[4] = 6; state->Init_Ctrl[38].val[4] = 1; state->Init_Ctrl[38].addr[5] = 32; state->Init_Ctrl[38].bit[5] = 7; state->Init_Ctrl[38].val[5] = 0; state->Init_Ctrl[39].Ctrl_Num = EN_CHP_LIN_B ; state->Init_Ctrl[39].size = 1 ; state->Init_Ctrl[39].addr[0] = 25; state->Init_Ctrl[39].bit[0] = 3; state->Init_Ctrl[39].val[0] = 1; state->CH_Ctrl_Num = CHCTRL_NUM ; state->CH_Ctrl[0].Ctrl_Num = DN_POLY ; state->CH_Ctrl[0].size = 2 ; state->CH_Ctrl[0].addr[0] = 68; state->CH_Ctrl[0].bit[0] = 6; state->CH_Ctrl[0].val[0] = 1; state->CH_Ctrl[0].addr[1] = 68; state->CH_Ctrl[0].bit[1] = 7; state->CH_Ctrl[0].val[1] = 1; state->CH_Ctrl[1].Ctrl_Num = DN_RFGAIN ; state->CH_Ctrl[1].size = 2 ; state->CH_Ctrl[1].addr[0] = 70; state->CH_Ctrl[1].bit[0] = 6; state->CH_Ctrl[1].val[0] = 1; state->CH_Ctrl[1].addr[1] = 70; state->CH_Ctrl[1].bit[1] = 7; state->CH_Ctrl[1].val[1] = 0; state->CH_Ctrl[2].Ctrl_Num = DN_CAP_RFLPF ; state->CH_Ctrl[2].size = 9 ; state->CH_Ctrl[2].addr[0] = 69; state->CH_Ctrl[2].bit[0] = 5; state->CH_Ctrl[2].val[0] = 0; state->CH_Ctrl[2].addr[1] = 69; state->CH_Ctrl[2].bit[1] = 6; state->CH_Ctrl[2].val[1] = 0; state->CH_Ctrl[2].addr[2] = 69; state->CH_Ctrl[2].bit[2] = 7; state->CH_Ctrl[2].val[2] = 0; state->CH_Ctrl[2].addr[3] = 68; state->CH_Ctrl[2].bit[3] = 0; state->CH_Ctrl[2].val[3] = 0; state->CH_Ctrl[2].addr[4] = 68; state->CH_Ctrl[2].bit[4] = 1; state->CH_Ctrl[2].val[4] = 0; state->CH_Ctrl[2].addr[5] = 68; state->CH_Ctrl[2].bit[5] = 2; state->CH_Ctrl[2].val[5] = 0; state->CH_Ctrl[2].addr[6] = 68; state->CH_Ctrl[2].bit[6] = 3; state->CH_Ctrl[2].val[6] = 0; state->CH_Ctrl[2].addr[7] = 68; state->CH_Ctrl[2].bit[7] = 4; state->CH_Ctrl[2].val[7] = 0; state->CH_Ctrl[2].addr[8] = 68; state->CH_Ctrl[2].bit[8] = 5; state->CH_Ctrl[2].val[8] = 0; state->CH_Ctrl[3].Ctrl_Num = DN_EN_VHFUHFBAR ; state->CH_Ctrl[3].size = 1 ; state->CH_Ctrl[3].addr[0] = 70; state->CH_Ctrl[3].bit[0] = 5; state->CH_Ctrl[3].val[0] = 0; state->CH_Ctrl[4].Ctrl_Num = DN_GAIN_ADJUST ; state->CH_Ctrl[4].size = 3 ; state->CH_Ctrl[4].addr[0] = 73; state->CH_Ctrl[4].bit[0] = 4; state->CH_Ctrl[4].val[0] = 0; state->CH_Ctrl[4].addr[1] = 73; state->CH_Ctrl[4].bit[1] = 5; state->CH_Ctrl[4].val[1] = 1; state->CH_Ctrl[4].addr[2] = 73; state->CH_Ctrl[4].bit[2] = 6; state->CH_Ctrl[4].val[2] = 0; state->CH_Ctrl[5].Ctrl_Num = DN_IQTNBUF_AMP ; state->CH_Ctrl[5].size = 4 ; state->CH_Ctrl[5].addr[0] = 70; state->CH_Ctrl[5].bit[0] = 0; state->CH_Ctrl[5].val[0] = 0; state->CH_Ctrl[5].addr[1] = 70; state->CH_Ctrl[5].bit[1] = 1; state->CH_Ctrl[5].val[1] = 0; state->CH_Ctrl[5].addr[2] = 70; state->CH_Ctrl[5].bit[2] = 2; state->CH_Ctrl[5].val[2] = 0; state->CH_Ctrl[5].addr[3] = 70; state->CH_Ctrl[5].bit[3] = 3; state->CH_Ctrl[5].val[3] = 0; state->CH_Ctrl[6].Ctrl_Num = DN_IQTNGNBFBIAS_BST ; state->CH_Ctrl[6].size = 1 ; state->CH_Ctrl[6].addr[0] = 70; state->CH_Ctrl[6].bit[0] = 4; state->CH_Ctrl[6].val[0] = 1; state->CH_Ctrl[7].Ctrl_Num = RFSYN_EN_OUTMUX ; state->CH_Ctrl[7].size = 1 ; state->CH_Ctrl[7].addr[0] = 111; state->CH_Ctrl[7].bit[0] = 4; state->CH_Ctrl[7].val[0] = 0; state->CH_Ctrl[8].Ctrl_Num = RFSYN_SEL_VCO_OUT ; state->CH_Ctrl[8].size = 1 ; state->CH_Ctrl[8].addr[0] = 111; state->CH_Ctrl[8].bit[0] = 7; state->CH_Ctrl[8].val[0] = 1; state->CH_Ctrl[9].Ctrl_Num = RFSYN_SEL_VCO_HI ; state->CH_Ctrl[9].size = 1 ; state->CH_Ctrl[9].addr[0] = 111; state->CH_Ctrl[9].bit[0] = 6; state->CH_Ctrl[9].val[0] = 1; state->CH_Ctrl[10].Ctrl_Num = RFSYN_SEL_DIVM ; state->CH_Ctrl[10].size = 1 ; state->CH_Ctrl[10].addr[0] = 111; state->CH_Ctrl[10].bit[0] = 5; state->CH_Ctrl[10].val[0] = 0; state->CH_Ctrl[11].Ctrl_Num = RFSYN_RF_DIV_BIAS ; state->CH_Ctrl[11].size = 2 ; state->CH_Ctrl[11].addr[0] = 110; state->CH_Ctrl[11].bit[0] = 0; state->CH_Ctrl[11].val[0] = 1; state->CH_Ctrl[11].addr[1] = 110; state->CH_Ctrl[11].bit[1] = 1; state->CH_Ctrl[11].val[1] = 0; state->CH_Ctrl[12].Ctrl_Num = DN_SEL_FREQ ; state->CH_Ctrl[12].size = 3 ; state->CH_Ctrl[12].addr[0] = 69; state->CH_Ctrl[12].bit[0] = 2; state->CH_Ctrl[12].val[0] = 0; state->CH_Ctrl[12].addr[1] = 69; state->CH_Ctrl[12].bit[1] = 3; state->CH_Ctrl[12].val[1] = 0; state->CH_Ctrl[12].addr[2] = 69; state->CH_Ctrl[12].bit[2] = 4; state->CH_Ctrl[12].val[2] = 0; state->CH_Ctrl[13].Ctrl_Num = RFSYN_VCO_BIAS ; state->CH_Ctrl[13].size = 6 ; state->CH_Ctrl[13].addr[0] = 110; state->CH_Ctrl[13].bit[0] = 2; state->CH_Ctrl[13].val[0] = 0; state->CH_Ctrl[13].addr[1] = 110; state->CH_Ctrl[13].bit[1] = 3; state->CH_Ctrl[13].val[1] = 0; state->CH_Ctrl[13].addr[2] = 110; state->CH_Ctrl[13].bit[2] = 4; state->CH_Ctrl[13].val[2] = 0; state->CH_Ctrl[13].addr[3] = 110; state->CH_Ctrl[13].bit[3] = 5; state->CH_Ctrl[13].val[3] = 0; state->CH_Ctrl[13].addr[4] = 110; state->CH_Ctrl[13].bit[4] = 6; state->CH_Ctrl[13].val[4] = 0; state->CH_Ctrl[13].addr[5] = 110; state->CH_Ctrl[13].bit[5] = 7; state->CH_Ctrl[13].val[5] = 1; state->CH_Ctrl[14].Ctrl_Num = CHCAL_INT_MOD_RF ; state->CH_Ctrl[14].size = 7 ; state->CH_Ctrl[14].addr[0] = 14; state->CH_Ctrl[14].bit[0] = 0; state->CH_Ctrl[14].val[0] = 0; state->CH_Ctrl[14].addr[1] = 14; state->CH_Ctrl[14].bit[1] = 1; state->CH_Ctrl[14].val[1] = 0; state->CH_Ctrl[14].addr[2] = 14; state->CH_Ctrl[14].bit[2] = 2; state->CH_Ctrl[14].val[2] = 0; state->CH_Ctrl[14].addr[3] = 14; state->CH_Ctrl[14].bit[3] = 3; state->CH_Ctrl[14].val[3] = 0; state->CH_Ctrl[14].addr[4] = 14; state->CH_Ctrl[14].bit[4] = 4; state->CH_Ctrl[14].val[4] = 0; state->CH_Ctrl[14].addr[5] = 14; state->CH_Ctrl[14].bit[5] = 5; state->CH_Ctrl[14].val[5] = 0; state->CH_Ctrl[14].addr[6] = 14; state->CH_Ctrl[14].bit[6] = 6; state->CH_Ctrl[14].val[6] = 0; state->CH_Ctrl[15].Ctrl_Num = CHCAL_FRAC_MOD_RF ; state->CH_Ctrl[15].size = 18 ; state->CH_Ctrl[15].addr[0] = 17; state->CH_Ctrl[15].bit[0] = 6; state->CH_Ctrl[15].val[0] = 0; state->CH_Ctrl[15].addr[1] = 17; state->CH_Ctrl[15].bit[1] = 7; state->CH_Ctrl[15].val[1] = 0; state->CH_Ctrl[15].addr[2] = 16; state->CH_Ctrl[15].bit[2] = 0; state->CH_Ctrl[15].val[2] = 0; state->CH_Ctrl[15].addr[3] = 16; state->CH_Ctrl[15].bit[3] = 1; state->CH_Ctrl[15].val[3] = 0; state->CH_Ctrl[15].addr[4] = 16; state->CH_Ctrl[15].bit[4] = 2; state->CH_Ctrl[15].val[4] = 0; state->CH_Ctrl[15].addr[5] = 16; state->CH_Ctrl[15].bit[5] = 3; state->CH_Ctrl[15].val[5] = 0; state->CH_Ctrl[15].addr[6] = 16; state->CH_Ctrl[15].bit[6] = 4; state->CH_Ctrl[15].val[6] = 0; state->CH_Ctrl[15].addr[7] = 16; state->CH_Ctrl[15].bit[7] = 5; state->CH_Ctrl[15].val[7] = 0; state->CH_Ctrl[15].addr[8] = 16; state->CH_Ctrl[15].bit[8] = 6; state->CH_Ctrl[15].val[8] = 0; state->CH_Ctrl[15].addr[9] = 16; state->CH_Ctrl[15].bit[9] = 7; state->CH_Ctrl[15].val[9] = 0; state->CH_Ctrl[15].addr[10] = 15; state->CH_Ctrl[15].bit[10] = 0; state->CH_Ctrl[15].val[10] = 0; state->CH_Ctrl[15].addr[11] = 15; state->CH_Ctrl[15].bit[11] = 1; state->CH_Ctrl[15].val[11] = 0; state->CH_Ctrl[15].addr[12] = 15; state->CH_Ctrl[15].bit[12] = 2; state->CH_Ctrl[15].val[12] = 0; state->CH_Ctrl[15].addr[13] = 15; state->CH_Ctrl[15].bit[13] = 3; state->CH_Ctrl[15].val[13] = 0; state->CH_Ctrl[15].addr[14] = 15; state->CH_Ctrl[15].bit[14] = 4; state->CH_Ctrl[15].val[14] = 0; state->CH_Ctrl[15].addr[15] = 15; state->CH_Ctrl[15].bit[15] = 5; state->CH_Ctrl[15].val[15] = 0; state->CH_Ctrl[15].addr[16] = 15; state->CH_Ctrl[15].bit[16] = 6; state->CH_Ctrl[15].val[16] = 1; state->CH_Ctrl[15].addr[17] = 15; state->CH_Ctrl[15].bit[17] = 7; state->CH_Ctrl[15].val[17] = 1; state->CH_Ctrl[16].Ctrl_Num = RFSYN_LPF_R ; state->CH_Ctrl[16].size = 5 ; state->CH_Ctrl[16].addr[0] = 112; state->CH_Ctrl[16].bit[0] = 0; state->CH_Ctrl[16].val[0] = 0; state->CH_Ctrl[16].addr[1] = 112; state->CH_Ctrl[16].bit[1] = 1; state->CH_Ctrl[16].val[1] = 0; state->CH_Ctrl[16].addr[2] = 112; state->CH_Ctrl[16].bit[2] = 2; state->CH_Ctrl[16].val[2] = 0; state->CH_Ctrl[16].addr[3] = 112; state->CH_Ctrl[16].bit[3] = 3; state->CH_Ctrl[16].val[3] = 0; state->CH_Ctrl[16].addr[4] = 112; state->CH_Ctrl[16].bit[4] = 4; state->CH_Ctrl[16].val[4] = 1; state->CH_Ctrl[17].Ctrl_Num = CHCAL_EN_INT_RF ; state->CH_Ctrl[17].size = 1 ; state->CH_Ctrl[17].addr[0] = 14; state->CH_Ctrl[17].bit[0] = 7; state->CH_Ctrl[17].val[0] = 0; state->CH_Ctrl[18].Ctrl_Num = TG_LO_DIVVAL ; state->CH_Ctrl[18].size = 4 ; state->CH_Ctrl[18].addr[0] = 107; state->CH_Ctrl[18].bit[0] = 3; state->CH_Ctrl[18].val[0] = 0; state->CH_Ctrl[18].addr[1] = 107; state->CH_Ctrl[18].bit[1] = 4; state->CH_Ctrl[18].val[1] = 0; state->CH_Ctrl[18].addr[2] = 107; state->CH_Ctrl[18].bit[2] = 5; state->CH_Ctrl[18].val[2] = 0; state->CH_Ctrl[18].addr[3] = 107; state->CH_Ctrl[18].bit[3] = 6; state->CH_Ctrl[18].val[3] = 0; state->CH_Ctrl[19].Ctrl_Num = TG_LO_SELVAL ; state->CH_Ctrl[19].size = 3 ; state->CH_Ctrl[19].addr[0] = 107; state->CH_Ctrl[19].bit[0] = 7; state->CH_Ctrl[19].val[0] = 1; state->CH_Ctrl[19].addr[1] = 106; state->CH_Ctrl[19].bit[1] = 0; state->CH_Ctrl[19].val[1] = 1; state->CH_Ctrl[19].addr[2] = 106; state->CH_Ctrl[19].bit[2] = 1; state->CH_Ctrl[19].val[2] = 1; state->CH_Ctrl[20].Ctrl_Num = TG_DIV_VAL ; state->CH_Ctrl[20].size = 11 ; state->CH_Ctrl[20].addr[0] = 109; state->CH_Ctrl[20].bit[0] = 2; state->CH_Ctrl[20].val[0] = 0; state->CH_Ctrl[20].addr[1] = 109; state->CH_Ctrl[20].bit[1] = 3; state->CH_Ctrl[20].val[1] = 0; state->CH_Ctrl[20].addr[2] = 109; state->CH_Ctrl[20].bit[2] = 4; state->CH_Ctrl[20].val[2] = 0; state->CH_Ctrl[20].addr[3] = 109; state->CH_Ctrl[20].bit[3] = 5; state->CH_Ctrl[20].val[3] = 0; state->CH_Ctrl[20].addr[4] = 109; state->CH_Ctrl[20].bit[4] = 6; state->CH_Ctrl[20].val[4] = 0; state->CH_Ctrl[20].addr[5] = 109; state->CH_Ctrl[20].bit[5] = 7; state->CH_Ctrl[20].val[5] = 0; state->CH_Ctrl[20].addr[6] = 108; state->CH_Ctrl[20].bit[6] = 0; state->CH_Ctrl[20].val[6] = 0; state->CH_Ctrl[20].addr[7] = 108; state->CH_Ctrl[20].bit[7] = 1; state->CH_Ctrl[20].val[7] = 0; state->CH_Ctrl[20].addr[8] = 108; state->CH_Ctrl[20].bit[8] = 2; state->CH_Ctrl[20].val[8] = 1; state->CH_Ctrl[20].addr[9] = 108; state->CH_Ctrl[20].bit[9] = 3; state->CH_Ctrl[20].val[9] = 1; state->CH_Ctrl[20].addr[10] = 108; state->CH_Ctrl[20].bit[10] = 4; state->CH_Ctrl[20].val[10] = 1; state->CH_Ctrl[21].Ctrl_Num = TG_VCO_BIAS ; state->CH_Ctrl[21].size = 6 ; state->CH_Ctrl[21].addr[0] = 106; state->CH_Ctrl[21].bit[0] = 2; state->CH_Ctrl[21].val[0] = 0; state->CH_Ctrl[21].addr[1] = 106; state->CH_Ctrl[21].bit[1] = 3; state->CH_Ctrl[21].val[1] = 0; state->CH_Ctrl[21].addr[2] = 106; state->CH_Ctrl[21].bit[2] = 4; state->CH_Ctrl[21].val[2] = 0; state->CH_Ctrl[21].addr[3] = 106; state->CH_Ctrl[21].bit[3] = 5; state->CH_Ctrl[21].val[3] = 0; state->CH_Ctrl[21].addr[4] = 106; state->CH_Ctrl[21].bit[4] = 6; state->CH_Ctrl[21].val[4] = 0; state->CH_Ctrl[21].addr[5] = 106; state->CH_Ctrl[21].bit[5] = 7; state->CH_Ctrl[21].val[5] = 1; state->CH_Ctrl[22].Ctrl_Num = SEQ_EXTPOWERUP ; state->CH_Ctrl[22].size = 1 ; state->CH_Ctrl[22].addr[0] = 138; state->CH_Ctrl[22].bit[0] = 4; state->CH_Ctrl[22].val[0] = 1; state->CH_Ctrl[23].Ctrl_Num = OVERRIDE_2 ; state->CH_Ctrl[23].size = 1 ; state->CH_Ctrl[23].addr[0] = 17; state->CH_Ctrl[23].bit[0] = 5; state->CH_Ctrl[23].val[0] = 0; state->CH_Ctrl[24].Ctrl_Num = OVERRIDE_3 ; state->CH_Ctrl[24].size = 1 ; state->CH_Ctrl[24].addr[0] = 111; state->CH_Ctrl[24].bit[0] = 3; state->CH_Ctrl[24].val[0] = 0; state->CH_Ctrl[25].Ctrl_Num = OVERRIDE_4 ; state->CH_Ctrl[25].size = 1 ; state->CH_Ctrl[25].addr[0] = 112; state->CH_Ctrl[25].bit[0] = 7; state->CH_Ctrl[25].val[0] = 0; state->CH_Ctrl[26].Ctrl_Num = SEQ_FSM_PULSE ; state->CH_Ctrl[26].size = 1 ; state->CH_Ctrl[26].addr[0] = 136; state->CH_Ctrl[26].bit[0] = 7; state->CH_Ctrl[26].val[0] = 0; state->CH_Ctrl[27].Ctrl_Num = GPIO_4B ; state->CH_Ctrl[27].size = 1 ; state->CH_Ctrl[27].addr[0] = 149; state->CH_Ctrl[27].bit[0] = 7; state->CH_Ctrl[27].val[0] = 0; state->CH_Ctrl[28].Ctrl_Num = GPIO_3B ; state->CH_Ctrl[28].size = 1 ; state->CH_Ctrl[28].addr[0] = 149; state->CH_Ctrl[28].bit[0] = 6; state->CH_Ctrl[28].val[0] = 0; state->CH_Ctrl[29].Ctrl_Num = GPIO_4 ; state->CH_Ctrl[29].size = 1 ; state->CH_Ctrl[29].addr[0] = 149; state->CH_Ctrl[29].bit[0] = 5; state->CH_Ctrl[29].val[0] = 1; state->CH_Ctrl[30].Ctrl_Num = GPIO_3 ; state->CH_Ctrl[30].size = 1 ; state->CH_Ctrl[30].addr[0] = 149; state->CH_Ctrl[30].bit[0] = 4; state->CH_Ctrl[30].val[0] = 1; state->CH_Ctrl[31].Ctrl_Num = GPIO_1B ; state->CH_Ctrl[31].size = 1 ; state->CH_Ctrl[31].addr[0] = 149; state->CH_Ctrl[31].bit[0] = 3; state->CH_Ctrl[31].val[0] = 0; state->CH_Ctrl[32].Ctrl_Num = DAC_A_ENABLE ; state->CH_Ctrl[32].size = 1 ; state->CH_Ctrl[32].addr[0] = 93; state->CH_Ctrl[32].bit[0] = 1; state->CH_Ctrl[32].val[0] = 0; state->CH_Ctrl[33].Ctrl_Num = DAC_B_ENABLE ; state->CH_Ctrl[33].size = 1 ; state->CH_Ctrl[33].addr[0] = 93; state->CH_Ctrl[33].bit[0] = 0; state->CH_Ctrl[33].val[0] = 0; state->CH_Ctrl[34].Ctrl_Num = DAC_DIN_A ; state->CH_Ctrl[34].size = 6 ; state->CH_Ctrl[34].addr[0] = 92; state->CH_Ctrl[34].bit[0] = 2; state->CH_Ctrl[34].val[0] = 0; state->CH_Ctrl[34].addr[1] = 92; state->CH_Ctrl[34].bit[1] = 3; state->CH_Ctrl[34].val[1] = 0; state->CH_Ctrl[34].addr[2] = 92; state->CH_Ctrl[34].bit[2] = 4; state->CH_Ctrl[34].val[2] = 0; state->CH_Ctrl[34].addr[3] = 92; state->CH_Ctrl[34].bit[3] = 5; state->CH_Ctrl[34].val[3] = 0; state->CH_Ctrl[34].addr[4] = 92; state->CH_Ctrl[34].bit[4] = 6; state->CH_Ctrl[34].val[4] = 0; state->CH_Ctrl[34].addr[5] = 92; state->CH_Ctrl[34].bit[5] = 7; state->CH_Ctrl[34].val[5] = 0; state->CH_Ctrl[35].Ctrl_Num = DAC_DIN_B ; state->CH_Ctrl[35].size = 6 ; state->CH_Ctrl[35].addr[0] = 93; state->CH_Ctrl[35].bit[0] = 2; state->CH_Ctrl[35].val[0] = 0; state->CH_Ctrl[35].addr[1] = 93; state->CH_Ctrl[35].bit[1] = 3; state->CH_Ctrl[35].val[1] = 0; state->CH_Ctrl[35].addr[2] = 93; state->CH_Ctrl[35].bit[2] = 4; state->CH_Ctrl[35].val[2] = 0; state->CH_Ctrl[35].addr[3] = 93; state->CH_Ctrl[35].bit[3] = 5; state->CH_Ctrl[35].val[3] = 0; state->CH_Ctrl[35].addr[4] = 93; state->CH_Ctrl[35].bit[4] = 6; state->CH_Ctrl[35].val[4] = 0; state->CH_Ctrl[35].addr[5] = 93; state->CH_Ctrl[35].bit[5] = 7; state->CH_Ctrl[35].val[5] = 0; #ifdef _MXL_PRODUCTION state->CH_Ctrl[36].Ctrl_Num = RFSYN_EN_DIV ; state->CH_Ctrl[36].size = 1 ; state->CH_Ctrl[36].addr[0] = 109; state->CH_Ctrl[36].bit[0] = 1; state->CH_Ctrl[36].val[0] = 1; state->CH_Ctrl[37].Ctrl_Num = RFSYN_DIVM ; state->CH_Ctrl[37].size = 2 ; state->CH_Ctrl[37].addr[0] = 112; state->CH_Ctrl[37].bit[0] = 5; state->CH_Ctrl[37].val[0] = 0; state->CH_Ctrl[37].addr[1] = 112; state->CH_Ctrl[37].bit[1] = 6; state->CH_Ctrl[37].val[1] = 0; state->CH_Ctrl[38].Ctrl_Num = DN_BYPASS_AGC_I2C ; state->CH_Ctrl[38].size = 1 ; state->CH_Ctrl[38].addr[0] = 65; state->CH_Ctrl[38].bit[0] = 1; state->CH_Ctrl[38].val[0] = 0; #endif return 0 ; } // MaxLinear source code - MXL5005_c.cpp // MXL5005.cpp : Defines the initialization routines for the DLL. // 2.6.12 void InitTunerControls(struct dvb_frontend *fe) { MXL5005_RegisterInit(fe); MXL5005_ControlInit(fe); #ifdef _MXL_INTERNAL MXL5005_MXLControlInit(fe); #endif } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_ConfigTuner // // // // Description: Configure MXL5005Tuner structure for desired // // Channel Bandwidth/Channel Frequency // // // // // // Functions used: // // MXL_SynthIFLO_Calc // // // // Inputs: // // Tuner_struct: structure defined at higher level // // Mode: Tuner Mode (Analog/Digital) // // IF_Mode: IF Mode ( Zero/Low ) // // Bandwidth: Filter Channel Bandwidth (in Hz) // // IF_out: Desired IF out Frequency (in Hz) // // Fxtal: Crystal Frerquency (in Hz) // // TOP: 0: Dual AGC; Value: take over point // // IF_OUT_LOAD: IF out load resistor (200/300 Ohms) // // CLOCK_OUT: 0: Turn off clock out; 1: turn on clock out // // DIV_OUT: 0: Div-1; 1: Div-4 // // CAPSELECT: 0: Disable On-chip pulling cap; 1: Enable // // EN_RSSI: 0: Disable RSSI; 1: Enable RSSI // // // // Outputs: // // Tuner // // // // Return: // // 0 : Successful // // > 0 : Failed // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL5005_TunerConfig(struct dvb_frontend *fe, u8 Mode, /* 0: Analog Mode ; 1: Digital Mode */ u8 IF_mode, /* for Analog Mode, 0: zero IF; 1: low IF */ u32 Bandwidth, /* filter channel bandwidth (6, 7, 8) */ u32 IF_out, /* Desired IF Out Frequency */ u32 Fxtal, /* XTAL Frequency */ u8 AGC_Mode, /* AGC Mode - Dual AGC: 0, Single AGC: 1 */ u16 TOP, /* 0: Dual AGC; Value: take over point */ u16 IF_OUT_LOAD, /* IF Out Load Resistor (200 / 300 Ohms) */ u8 CLOCK_OUT, /* 0: turn off clock out; 1: turn on clock out */ u8 DIV_OUT, /* 0: Div-1; 1: Div-4 */ u8 CAPSELECT, /* 0: disable On-Chip pulling cap; 1: enable */ u8 EN_RSSI, /* 0: disable RSSI; 1: enable RSSI */ u8 Mod_Type, /* Modulation Type; */ /* 0 - Default; 1 - DVB-T; 2 - ATSC; 3 - QAM; 4 - Analog Cable */ u8 TF_Type /* Tracking Filter */ /* 0 - Default; 1 - Off; 2 - Type C; 3 - Type C-H */ ) { struct mxl5005s_state *state = fe->tuner_priv; u16 status = 0; state->Mode = Mode; state->IF_Mode = IF_mode; state->Chan_Bandwidth = Bandwidth; state->IF_OUT = IF_out; state->Fxtal = Fxtal; state->AGC_Mode = AGC_Mode; state->TOP = TOP; state->IF_OUT_LOAD = IF_OUT_LOAD; state->CLOCK_OUT = CLOCK_OUT; state->DIV_OUT = DIV_OUT; state->CAPSELECT = CAPSELECT; state->EN_RSSI = EN_RSSI; state->Mod_Type = Mod_Type; state->TF_Type = TF_Type; /* Initialize all the controls and registers */ InitTunerControls(fe); /* Synthesizer LO frequency calculation */ MXL_SynthIFLO_Calc(fe); return status; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_SynthIFLO_Calc // // // // Description: Calculate Internal IF-LO Frequency // // // // Globals: // // NONE // // // // Functions used: // // NONE // // // // Inputs: // // Tuner_struct: structure defined at higher level // // // // Outputs: // // Tuner // // // // Return: // // 0 : Successful // // > 0 : Failed // // // /////////////////////////////////////////////////////////////////////////////// void MXL_SynthIFLO_Calc(struct dvb_frontend *fe) { struct mxl5005s_state *state = fe->tuner_priv; if (state->Mode == 1) /* Digital Mode */ state->IF_LO = state->IF_OUT; else /* Analog Mode */ { if(state->IF_Mode == 0) /* Analog Zero IF mode */ state->IF_LO = state->IF_OUT + 400000; else /* Analog Low IF mode */ state->IF_LO = state->IF_OUT + state->Chan_Bandwidth/2; } } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_SynthRFTGLO_Calc // // // // Description: Calculate Internal RF-LO frequency and // // internal Tone-Gen(TG)-LO frequency // // // // Globals: // // NONE // // // // Functions used: // // NONE // // // // Inputs: // // Tuner_struct: structure defined at higher level // // // // Outputs: // // Tuner // // // // Return: // // 0 : Successful // // > 0 : Failed // // // /////////////////////////////////////////////////////////////////////////////// void MXL_SynthRFTGLO_Calc(struct dvb_frontend *fe) { struct mxl5005s_state *state = fe->tuner_priv; if (state->Mode == 1) /* Digital Mode */ { //remove 20.48MHz setting for 2.6.10 state->RF_LO = state->RF_IN; state->TG_LO = state->RF_IN - 750000; //change for 2.6.6 } else /* Analog Mode */ { if(state->IF_Mode == 0) /* Analog Zero IF mode */ { state->RF_LO = state->RF_IN - 400000; state->TG_LO = state->RF_IN - 1750000; } else /* Analog Low IF mode */ { state->RF_LO = state->RF_IN - state->Chan_Bandwidth/2; state->TG_LO = state->RF_IN - state->Chan_Bandwidth + 500000; } } } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_OverwriteICDefault // // // // Description: Overwrite the Default Register Setting // // // // // // Functions used: // // // // Inputs: // // Tuner_struct: structure defined at higher level // // Outputs: // // Tuner // // // // Return: // // 0 : Successful // // > 0 : Failed // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_OverwriteICDefault(struct dvb_frontend *fe) { u16 status = 0; status += MXL_ControlWrite(fe, OVERRIDE_1, 1); status += MXL_ControlWrite(fe, OVERRIDE_2, 1); status += MXL_ControlWrite(fe, OVERRIDE_3, 1); status += MXL_ControlWrite(fe, OVERRIDE_4, 1); return status; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_BlockInit // // // // Description: Tuner Initialization as a function of 'User Settings' // // * User settings in Tuner strcuture must be assigned // // first // // // // Globals: // // NONE // // // // Functions used: // // Tuner_struct: structure defined at higher level // // // // Inputs: // // Tuner : Tuner structure defined at higher level // // // // Outputs: // // Tuner // // // // Return: // // 0 : Successful // // > 0 : Failed // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_BlockInit(struct dvb_frontend *fe) { struct mxl5005s_state *state = fe->tuner_priv; u16 status = 0; status += MXL_OverwriteICDefault(fe); /* Downconverter Control Dig Ana */ status += MXL_ControlWrite(fe, DN_IQTN_AMP_CUT, state->Mode ? 1 : 0); /* Filter Control Dig Ana */ status += MXL_ControlWrite(fe, BB_MODE, state->Mode ? 0 : 1); status += MXL_ControlWrite(fe, BB_BUF, state->Mode ? 3 : 2); status += MXL_ControlWrite(fe, BB_BUF_OA, state->Mode ? 1 : 0); status += MXL_ControlWrite(fe, BB_IQSWAP, state->Mode ? 0 : 1); status += MXL_ControlWrite(fe, BB_INITSTATE_DLPF_TUNE, 0); /* Initialize Low-Pass Filter */ if (state->Mode) { /* Digital Mode */ switch (state->Chan_Bandwidth) { case 8000000: status += MXL_ControlWrite(fe, BB_DLPF_BANDSEL, 0); break; case 7000000: status += MXL_ControlWrite(fe, BB_DLPF_BANDSEL, 2); break; case 6000000: printk("%s() doing 6MHz digital\n", __func__); status += MXL_ControlWrite(fe, BB_DLPF_BANDSEL, 3); break; } } else { /* Analog Mode */ switch (state->Chan_Bandwidth) { case 8000000: /* Low Zero */ status += MXL_ControlWrite(fe, BB_ALPF_BANDSELECT, (state->IF_Mode ? 0 : 3)); break; case 7000000: status += MXL_ControlWrite(fe, BB_ALPF_BANDSELECT, (state->IF_Mode ? 1 : 4)); break; case 6000000: status += MXL_ControlWrite(fe, BB_ALPF_BANDSELECT, (state->IF_Mode ? 2 : 5)); break; } } /* Charge Pump Control Dig Ana */ status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, state->Mode ? 5 : 8); status += MXL_ControlWrite(fe, RFSYN_EN_CHP_HIGAIN, state->Mode ? 1 : 1); status += MXL_ControlWrite(fe, EN_CHP_LIN_B, state->Mode ? 0 : 0); /* AGC TOP Control */ if (state->AGC_Mode == 0) /* Dual AGC */ { status += MXL_ControlWrite(fe, AGC_IF, 15); status += MXL_ControlWrite(fe, AGC_RF, 15); } else /* Single AGC Mode Dig Ana */ status += MXL_ControlWrite(fe, AGC_RF, state->Mode ? 15 : 12); if (state->TOP == 55) /* TOP == 5.5 */ status += MXL_ControlWrite(fe, AGC_IF, 0x0); if (state->TOP == 72) /* TOP == 7.2 */ status += MXL_ControlWrite(fe, AGC_IF, 0x1); if (state->TOP == 92) /* TOP == 9.2 */ status += MXL_ControlWrite(fe, AGC_IF, 0x2); if (state->TOP == 110) /* TOP == 11.0 */ status += MXL_ControlWrite(fe, AGC_IF, 0x3); if (state->TOP == 129) /* TOP == 12.9 */ status += MXL_ControlWrite(fe, AGC_IF, 0x4); if (state->TOP == 147) /* TOP == 14.7 */ status += MXL_ControlWrite(fe, AGC_IF, 0x5); if (state->TOP == 168) /* TOP == 16.8 */ status += MXL_ControlWrite(fe, AGC_IF, 0x6); if (state->TOP == 194) /* TOP == 19.4 */ status += MXL_ControlWrite(fe, AGC_IF, 0x7); if (state->TOP == 212) /* TOP == 21.2 */ status += MXL_ControlWrite(fe, AGC_IF, 0x9); if (state->TOP == 232) /* TOP == 23.2 */ status += MXL_ControlWrite(fe, AGC_IF, 0xA); if (state->TOP == 252) /* TOP == 25.2 */ status += MXL_ControlWrite(fe, AGC_IF, 0xB); if (state->TOP == 271) /* TOP == 27.1 */ status += MXL_ControlWrite(fe, AGC_IF, 0xC); if (state->TOP == 292) /* TOP == 29.2 */ status += MXL_ControlWrite(fe, AGC_IF, 0xD); if (state->TOP == 317) /* TOP == 31.7 */ status += MXL_ControlWrite(fe, AGC_IF, 0xE); if (state->TOP == 349) /* TOP == 34.9 */ status += MXL_ControlWrite(fe, AGC_IF, 0xF); /* IF Synthesizer Control */ status += MXL_IFSynthInit(fe); /* IF UpConverter Control */ if (state->IF_OUT_LOAD == 200) { status += MXL_ControlWrite(fe, DRV_RES_SEL, 6); status += MXL_ControlWrite(fe, I_DRIVER, 2); } if (state->IF_OUT_LOAD == 300) { status += MXL_ControlWrite(fe, DRV_RES_SEL, 4); status += MXL_ControlWrite(fe, I_DRIVER, 1); } /* Anti-Alias Filtering Control * initialise Anti-Aliasing Filter */ if (state->Mode) { /* Digital Mode */ if (state->IF_OUT >= 4000000UL && state->IF_OUT <= 6280000UL) { status += MXL_ControlWrite(fe, EN_AAF, 1); status += MXL_ControlWrite(fe, EN_3P, 1); status += MXL_ControlWrite(fe, EN_AUX_3P, 1); status += MXL_ControlWrite(fe, SEL_AAF_BAND, 0); } if ((state->IF_OUT == 36125000UL) || (state->IF_OUT == 36150000UL)) { status += MXL_ControlWrite(fe, EN_AAF, 1); status += MXL_ControlWrite(fe, EN_3P, 1); status += MXL_ControlWrite(fe, EN_AUX_3P, 1); status += MXL_ControlWrite(fe, SEL_AAF_BAND, 1); } if (state->IF_OUT > 36150000UL) { status += MXL_ControlWrite(fe, EN_AAF, 0); status += MXL_ControlWrite(fe, EN_3P, 1); status += MXL_ControlWrite(fe, EN_AUX_3P, 1); status += MXL_ControlWrite(fe, SEL_AAF_BAND, 1); } } else { /* Analog Mode */ if (state->IF_OUT >= 4000000UL && state->IF_OUT <= 5000000UL) { status += MXL_ControlWrite(fe, EN_AAF, 1); status += MXL_ControlWrite(fe, EN_3P, 1); status += MXL_ControlWrite(fe, EN_AUX_3P, 1); status += MXL_ControlWrite(fe, SEL_AAF_BAND, 0); } if (state->IF_OUT > 5000000UL) { status += MXL_ControlWrite(fe, EN_AAF, 0); status += MXL_ControlWrite(fe, EN_3P, 0); status += MXL_ControlWrite(fe, EN_AUX_3P, 0); status += MXL_ControlWrite(fe, SEL_AAF_BAND, 0); } } /* Demod Clock Out */ if (state->CLOCK_OUT) status += MXL_ControlWrite(fe, SEQ_ENCLK16_CLK_OUT, 1); else status += MXL_ControlWrite(fe, SEQ_ENCLK16_CLK_OUT, 0); if (state->DIV_OUT == 1) status += MXL_ControlWrite(fe, SEQ_SEL4_16B, 1); if (state->DIV_OUT == 0) status += MXL_ControlWrite(fe, SEQ_SEL4_16B, 0); /* Crystal Control */ if (state->CAPSELECT) status += MXL_ControlWrite(fe, XTAL_CAPSELECT, 1); else status += MXL_ControlWrite(fe, XTAL_CAPSELECT, 0); if (state->Fxtal >= 12000000UL && state->Fxtal <= 16000000UL) status += MXL_ControlWrite(fe, IF_SEL_DBL, 1); if (state->Fxtal > 16000000UL && state->Fxtal <= 32000000UL) status += MXL_ControlWrite(fe, IF_SEL_DBL, 0); if (state->Fxtal >= 12000000UL && state->Fxtal <= 22000000UL) status += MXL_ControlWrite(fe, RFSYN_R_DIV, 3); if (state->Fxtal > 22000000UL && state->Fxtal <= 32000000UL) status += MXL_ControlWrite(fe, RFSYN_R_DIV, 0); /* Misc Controls */ if (state->Mode == 0 && state->IF_Mode == 1) /* Analog LowIF mode */ status += MXL_ControlWrite(fe, SEQ_EXTIQFSMPULSE, 0); else status += MXL_ControlWrite(fe, SEQ_EXTIQFSMPULSE, 1); /* status += MXL_ControlRead(fe, IF_DIVVAL, &IF_DIVVAL_Val); */ /* Set TG_R_DIV */ status += MXL_ControlWrite(fe, TG_R_DIV, MXL_Ceiling(state->Fxtal, 1000000)); /* Apply Default value to BB_INITSTATE_DLPF_TUNE */ /* RSSI Control */ if (state->EN_RSSI) { status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1); status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1); status += MXL_ControlWrite(fe, AGC_EN_RSSI, 1); status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1); /* RSSI reference point */ status += MXL_ControlWrite(fe, RFA_RSSI_REF, 2); status += MXL_ControlWrite(fe, RFA_RSSI_REFH, 3); status += MXL_ControlWrite(fe, RFA_RSSI_REFL, 1); /* TOP point */ status += MXL_ControlWrite(fe, RFA_FLR, 0); status += MXL_ControlWrite(fe, RFA_CEIL, 12); } /* Modulation type bit settings * Override the control values preset */ if (state->Mod_Type == MXL_DVBT) /* DVB-T Mode */ { state->AGC_Mode = 1; /* Single AGC Mode */ /* Enable RSSI */ status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1); status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1); status += MXL_ControlWrite(fe, AGC_EN_RSSI, 1); status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1); /* RSSI reference point */ status += MXL_ControlWrite(fe, RFA_RSSI_REF, 3); status += MXL_ControlWrite(fe, RFA_RSSI_REFH, 5); status += MXL_ControlWrite(fe, RFA_RSSI_REFL, 1); /* TOP point */ status += MXL_ControlWrite(fe, RFA_FLR, 2); status += MXL_ControlWrite(fe, RFA_CEIL, 13); if (state->IF_OUT <= 6280000UL) /* Low IF */ status += MXL_ControlWrite(fe, BB_IQSWAP, 0); else /* High IF */ status += MXL_ControlWrite(fe, BB_IQSWAP, 1); } if (state->Mod_Type == MXL_ATSC) /* ATSC Mode */ { state->AGC_Mode = 1; /* Single AGC Mode */ /* Enable RSSI */ status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1); status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1); status += MXL_ControlWrite(fe, AGC_EN_RSSI, 1); status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1); /* RSSI reference point */ status += MXL_ControlWrite(fe, RFA_RSSI_REF, 2); status += MXL_ControlWrite(fe, RFA_RSSI_REFH, 4); status += MXL_ControlWrite(fe, RFA_RSSI_REFL, 1); /* TOP point */ status += MXL_ControlWrite(fe, RFA_FLR, 2); status += MXL_ControlWrite(fe, RFA_CEIL, 13); status += MXL_ControlWrite(fe, BB_INITSTATE_DLPF_TUNE, 1); status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 5); /* Low Zero */ if (state->IF_OUT <= 6280000UL) /* Low IF */ status += MXL_ControlWrite(fe, BB_IQSWAP, 0); else /* High IF */ status += MXL_ControlWrite(fe, BB_IQSWAP, 1); } if (state->Mod_Type == MXL_QAM) /* QAM Mode */ { state->Mode = MXL_DIGITAL_MODE; /* state->AGC_Mode = 1; */ /* Single AGC Mode */ /* Disable RSSI */ /* change here for v2.6.5 */ status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1); status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1); status += MXL_ControlWrite(fe, AGC_EN_RSSI, 0); status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1); /* RSSI reference point */ status += MXL_ControlWrite(fe, RFA_RSSI_REFH, 5); status += MXL_ControlWrite(fe, RFA_RSSI_REF, 3); status += MXL_ControlWrite(fe, RFA_RSSI_REFL, 2); status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 3); /* change here for v2.6.5 */ if (state->IF_OUT <= 6280000UL) /* Low IF */ status += MXL_ControlWrite(fe, BB_IQSWAP, 0); else /* High IF */ status += MXL_ControlWrite(fe, BB_IQSWAP, 1); status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 2); } if (state->Mod_Type == MXL_ANALOG_CABLE) { /* Analog Cable Mode */ /* state->Mode = MXL_DIGITAL_MODE; */ state->AGC_Mode = 1; /* Single AGC Mode */ /* Disable RSSI */ status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1); status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1); status += MXL_ControlWrite(fe, AGC_EN_RSSI, 0); status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1); status += MXL_ControlWrite(fe, AGC_IF, 1); /* change for 2.6.3 */ status += MXL_ControlWrite(fe, AGC_RF, 15); status += MXL_ControlWrite(fe, BB_IQSWAP, 1); } if (state->Mod_Type == MXL_ANALOG_OTA) { /* Analog OTA Terrestrial mode add for 2.6.7 */ /* state->Mode = MXL_ANALOG_MODE; */ /* Enable RSSI */ status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1); status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1); status += MXL_ControlWrite(fe, AGC_EN_RSSI, 1); status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1); /* RSSI reference point */ status += MXL_ControlWrite(fe, RFA_RSSI_REFH, 5); status += MXL_ControlWrite(fe, RFA_RSSI_REF, 3); status += MXL_ControlWrite(fe, RFA_RSSI_REFL, 2); status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 3); status += MXL_ControlWrite(fe, BB_IQSWAP, 1); } /* RSSI disable */ if(state->EN_RSSI == 0) { status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1); status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1); status += MXL_ControlWrite(fe, AGC_EN_RSSI, 0); status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1); } return status; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_IFSynthInit // // // // Description: Tuner IF Synthesizer related register initialization // // // // Globals: // // NONE // // // // Functions used: // // Tuner_struct: structure defined at higher level // // // // Inputs: // // Tuner : Tuner structure defined at higher level // // // // Outputs: // // Tuner // // // // Return: // // 0 : Successful // // > 0 : Failed // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_IFSynthInit(struct dvb_frontend *fe) { struct mxl5005s_state *state = fe->tuner_priv; u16 status = 0 ; // Declare Local Variables u32 Fref = 0 ; u32 Kdbl, intModVal ; u32 fracModVal ; Kdbl = 2 ; if (state->Fxtal >= 12000000UL && state->Fxtal <= 16000000UL) Kdbl = 2 ; if (state->Fxtal > 16000000UL && state->Fxtal <= 32000000UL) Kdbl = 1 ; // // IF Synthesizer Control // if (state->Mode == 0 && state->IF_Mode == 1) // Analog Low IF mode { if (state->IF_LO == 41000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 328000000UL ; } if (state->IF_LO == 47000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 376000000UL ; } if (state->IF_LO == 54000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x10) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 324000000UL ; } if (state->IF_LO == 60000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x10) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 360000000UL ; } if (state->IF_LO == 39250000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 314000000UL ; } if (state->IF_LO == 39650000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 317200000UL ; } if (state->IF_LO == 40150000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 321200000UL ; } if (state->IF_LO == 40650000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 325200000UL ; } } if (state->Mode || (state->Mode == 0 && state->IF_Mode == 0)) { if (state->IF_LO == 57000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x10) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 342000000UL ; } if (state->IF_LO == 44000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 352000000UL ; } if (state->IF_LO == 43750000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 350000000UL ; } if (state->IF_LO == 36650000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 366500000UL ; } if (state->IF_LO == 36150000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 361500000UL ; } if (state->IF_LO == 36000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 360000000UL ; } if (state->IF_LO == 35250000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 352500000UL ; } if (state->IF_LO == 34750000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 347500000UL ; } if (state->IF_LO == 6280000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x07) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 376800000UL ; } if (state->IF_LO == 5000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x09) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 360000000UL ; } if (state->IF_LO == 4500000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x06) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 360000000UL ; } if (state->IF_LO == 4570000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x06) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 365600000UL ; } if (state->IF_LO == 4000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x05) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 360000000UL ; } if (state->IF_LO == 57400000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x10) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 344400000UL ; } if (state->IF_LO == 44400000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 355200000UL ; } if (state->IF_LO == 44150000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x08) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 353200000UL ; } if (state->IF_LO == 37050000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 370500000UL ; } if (state->IF_LO == 36550000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 365500000UL ; } if (state->IF_LO == 36125000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x04) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 361250000UL ; } if (state->IF_LO == 6000000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x07) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 360000000UL ; } if (state->IF_LO == 5400000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x07) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 324000000UL ; } if (state->IF_LO == 5380000UL) { printk("%s() doing 5.38\n", __func__); status += MXL_ControlWrite(fe, IF_DIVVAL, 0x07) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x0C) ; Fref = 322800000UL ; } if (state->IF_LO == 5200000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x09) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 374400000UL ; } if (state->IF_LO == 4900000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x09) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 352800000UL ; } if (state->IF_LO == 4400000UL) { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x06) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 352000000UL ; } if (state->IF_LO == 4063000UL) //add for 2.6.8 { status += MXL_ControlWrite(fe, IF_DIVVAL, 0x05) ; status += MXL_ControlWrite(fe, IF_VCO_BIAS, 0x08) ; Fref = 365670000UL ; } } // CHCAL_INT_MOD_IF // CHCAL_FRAC_MOD_IF intModVal = Fref / (state->Fxtal * Kdbl/2) ; status += MXL_ControlWrite(fe, CHCAL_INT_MOD_IF, intModVal ) ; fracModVal = (2<<15)*(Fref/1000 - (state->Fxtal/1000 * Kdbl/2) * intModVal); fracModVal = fracModVal / ((state->Fxtal * Kdbl/2)/1000) ; status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_IF, fracModVal) ; return status ; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_GetXtalInt // // // // Description: return the Crystal Integration Value for // // TG_VCO_BIAS calculation // // // // Globals: // // NONE // // // // Functions used: // // NONE // // // // Inputs: // // Crystal Frequency Value in Hz // // // // Outputs: // // Calculated Crystal Frequency Integration Value // // // // Return: // // 0 : Successful // // > 0 : Failed // // // /////////////////////////////////////////////////////////////////////////////// u32 MXL_GetXtalInt(u32 Xtal_Freq) { if ((Xtal_Freq % 1000000) == 0) return (Xtal_Freq / 10000) ; else return (((Xtal_Freq / 1000000) + 1)*100) ; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL5005_TuneRF // // // // Description: Set control names to tune to requested RF_IN frequency // // // // Globals: // // None // // // // Functions used: // // MXL_SynthRFTGLO_Calc // // MXL5005_ControlWrite // // MXL_GetXtalInt // // // // Inputs: // // Tuner : Tuner structure defined at higher level // // // // Outputs: // // Tuner // // // // Return: // // 0 : Successful // // 1 : Unsuccessful // /////////////////////////////////////////////////////////////////////////////// u16 MXL_TuneRF(struct dvb_frontend *fe, u32 RF_Freq) { struct mxl5005s_state *state = fe->tuner_priv; // Declare Local Variables u16 status = 0; u32 divider_val, E3, E4, E5, E5A; u32 Fmax, Fmin, FmaxBin, FminBin; u32 Kdbl_RF = 2; u32 tg_divval; u32 tg_lo; u32 Xtal_Int; u32 Fref_TG; u32 Fvco; // u32 temp; Xtal_Int = MXL_GetXtalInt(state->Fxtal); state->RF_IN = RF_Freq; MXL_SynthRFTGLO_Calc(fe); if (state->Fxtal >= 12000000UL && state->Fxtal <= 22000000UL) Kdbl_RF = 2; if (state->Fxtal > 22000000 && state->Fxtal <= 32000000) Kdbl_RF = 1; // // Downconverter Controls // // Look-Up Table Implementation for: // DN_POLY // DN_RFGAIN // DN_CAP_RFLPF // DN_EN_VHFUHFBAR // DN_GAIN_ADJUST // Change the boundary reference from RF_IN to RF_LO if (state->RF_LO < 40000000UL) { return -1; } if (state->RF_LO >= 40000000UL && state->RF_LO <= 75000000UL) { // Look-Up Table implementation status += MXL_ControlWrite(fe, DN_POLY, 2); status += MXL_ControlWrite(fe, DN_RFGAIN, 3); status += MXL_ControlWrite(fe, DN_CAP_RFLPF, 423); status += MXL_ControlWrite(fe, DN_EN_VHFUHFBAR, 1); status += MXL_ControlWrite(fe, DN_GAIN_ADJUST, 1); } if (state->RF_LO > 75000000UL && state->RF_LO <= 100000000UL) { // Look-Up Table implementation status += MXL_ControlWrite(fe, DN_POLY, 3); status += MXL_ControlWrite(fe, DN_RFGAIN, 3); status += MXL_ControlWrite(fe, DN_CAP_RFLPF, 222); status += MXL_ControlWrite(fe, DN_EN_VHFUHFBAR, 1); status += MXL_ControlWrite(fe, DN_GAIN_ADJUST, 1); } if (state->RF_LO > 100000000UL && state->RF_LO <= 150000000UL) { // Look-Up Table implementation status += MXL_ControlWrite(fe, DN_POLY, 3); status += MXL_ControlWrite(fe, DN_RFGAIN, 3); status += MXL_ControlWrite(fe, DN_CAP_RFLPF, 147); status += MXL_ControlWrite(fe, DN_EN_VHFUHFBAR, 1); status += MXL_ControlWrite(fe, DN_GAIN_ADJUST, 2); } if (state->RF_LO > 150000000UL && state->RF_LO <= 200000000UL) { // Look-Up Table implementation status += MXL_ControlWrite(fe, DN_POLY, 3); status += MXL_ControlWrite(fe, DN_RFGAIN, 3); status += MXL_ControlWrite(fe, DN_CAP_RFLPF, 9); status += MXL_ControlWrite(fe, DN_EN_VHFUHFBAR, 1); status += MXL_ControlWrite(fe, DN_GAIN_ADJUST, 2); } if (state->RF_LO > 200000000UL && state->RF_LO <= 300000000UL) { // Look-Up Table implementation status += MXL_ControlWrite(fe, DN_POLY, 3) ; status += MXL_ControlWrite(fe, DN_RFGAIN, 3) ; status += MXL_ControlWrite(fe, DN_CAP_RFLPF, 0) ; status += MXL_ControlWrite(fe, DN_EN_VHFUHFBAR, 1) ; status += MXL_ControlWrite(fe, DN_GAIN_ADJUST, 3) ; } if (state->RF_LO > 300000000UL && state->RF_LO <= 650000000UL) { // Look-Up Table implementation status += MXL_ControlWrite(fe, DN_POLY, 3) ; status += MXL_ControlWrite(fe, DN_RFGAIN, 1) ; status += MXL_ControlWrite(fe, DN_CAP_RFLPF, 0) ; status += MXL_ControlWrite(fe, DN_EN_VHFUHFBAR, 0) ; status += MXL_ControlWrite(fe, DN_GAIN_ADJUST, 3) ; } if (state->RF_LO > 650000000UL && state->RF_LO <= 900000000UL) { // Look-Up Table implementation status += MXL_ControlWrite(fe, DN_POLY, 3) ; status += MXL_ControlWrite(fe, DN_RFGAIN, 2) ; status += MXL_ControlWrite(fe, DN_CAP_RFLPF, 0) ; status += MXL_ControlWrite(fe, DN_EN_VHFUHFBAR, 0) ; status += MXL_ControlWrite(fe, DN_GAIN_ADJUST, 3) ; } if (state->RF_LO > 900000000UL) { return -1; } // DN_IQTNBUF_AMP // DN_IQTNGNBFBIAS_BST if (state->RF_LO >= 40000000UL && state->RF_LO <= 75000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 75000000UL && state->RF_LO <= 100000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 100000000UL && state->RF_LO <= 150000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 150000000UL && state->RF_LO <= 200000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 200000000UL && state->RF_LO <= 300000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 300000000UL && state->RF_LO <= 400000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 400000000UL && state->RF_LO <= 450000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 450000000UL && state->RF_LO <= 500000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 500000000UL && state->RF_LO <= 550000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 550000000UL && state->RF_LO <= 600000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 600000000UL && state->RF_LO <= 650000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 650000000UL && state->RF_LO <= 700000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 700000000UL && state->RF_LO <= 750000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 750000000UL && state->RF_LO <= 800000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 1); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 0); } if (state->RF_LO > 800000000UL && state->RF_LO <= 850000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 10); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 1); } if (state->RF_LO > 850000000UL && state->RF_LO <= 900000000UL) { status += MXL_ControlWrite(fe, DN_IQTNBUF_AMP, 10); status += MXL_ControlWrite(fe, DN_IQTNGNBFBIAS_BST, 1); } // // Set RF Synth and LO Path Control // // Look-Up table implementation for: // RFSYN_EN_OUTMUX // RFSYN_SEL_VCO_OUT // RFSYN_SEL_VCO_HI // RFSYN_SEL_DIVM // RFSYN_RF_DIV_BIAS // DN_SEL_FREQ // // Set divider_val, Fmax, Fmix to use in Equations FminBin = 28000000UL ; FmaxBin = 42500000UL ; if (state->RF_LO >= 40000000UL && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 1); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0); status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1); status += MXL_ControlWrite(fe, DN_SEL_FREQ, 1); divider_val = 64 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 42500000UL ; FmaxBin = 56000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 1); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0); status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1); status += MXL_ControlWrite(fe, DN_SEL_FREQ, 1); divider_val = 64 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 56000000UL ; FmaxBin = 85000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 1) ; divider_val = 32 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 85000000UL ; FmaxBin = 112000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 1) ; divider_val = 32 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 112000000UL ; FmaxBin = 170000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 2) ; divider_val = 16 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 170000000UL ; FmaxBin = 225000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 2) ; divider_val = 16 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 225000000UL ; FmaxBin = 300000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 4) ; divider_val = 8 ; Fmax = 340000000UL ; Fmin = FminBin ; } FminBin = 300000000UL ; FmaxBin = 340000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0) ; divider_val = 8 ; Fmax = FmaxBin ; Fmin = 225000000UL ; } FminBin = 340000000UL ; FmaxBin = 450000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 2) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0) ; divider_val = 8 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 450000000UL ; FmaxBin = 680000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 1) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0) ; divider_val = 4 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 680000000UL ; FmaxBin = 900000000UL ; if (state->RF_LO > FminBin && state->RF_LO <= FmaxBin) { status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1) ; status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 1) ; status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1) ; status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0) ; divider_val = 4 ; Fmax = FmaxBin ; Fmin = FminBin ; } // CHCAL_INT_MOD_RF // CHCAL_FRAC_MOD_RF // RFSYN_LPF_R // CHCAL_EN_INT_RF // Equation E3 // RFSYN_VCO_BIAS E3 = (((Fmax-state->RF_LO)/1000)*32)/((Fmax-Fmin)/1000) + 8 ; status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, E3) ; // Equation E4 // CHCAL_INT_MOD_RF E4 = (state->RF_LO*divider_val/1000)/(2*state->Fxtal*Kdbl_RF/1000) ; MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, E4) ; // Equation E5 // CHCAL_FRAC_MOD_RF // CHCAL_EN_INT_RF E5 = ((2<<17)*(state->RF_LO/10000*divider_val - (E4*(2*state->Fxtal*Kdbl_RF)/10000)))/(2*state->Fxtal*Kdbl_RF/10000) ; status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, E5) ; // Equation E5A // RFSYN_LPF_R E5A = (((Fmax - state->RF_LO)/1000)*4/((Fmax-Fmin)/1000)) + 1 ; status += MXL_ControlWrite(fe, RFSYN_LPF_R, E5A) ; // Euqation E5B // CHCAL_EN_INIT_RF status += MXL_ControlWrite(fe, CHCAL_EN_INT_RF, ((E5 == 0) ? 1 : 0)); //if (E5 == 0) // status += MXL_ControlWrite(fe, CHCAL_EN_INT_RF, 1); //else // status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, E5) ; // // Set TG Synth // // Look-Up table implementation for: // TG_LO_DIVVAL // TG_LO_SELVAL // // Set divider_val, Fmax, Fmix to use in Equations if (state->TG_LO < 33000000UL) { return -1; } FminBin = 33000000UL ; FmaxBin = 50000000UL ; if (state->TG_LO >= FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x6) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x0) ; divider_val = 36 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 50000000UL ; FmaxBin = 67000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x1) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x0) ; divider_val = 24 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 67000000UL ; FmaxBin = 100000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0xC) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x2) ; divider_val = 18 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 100000000UL ; FmaxBin = 150000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x8) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x2) ; divider_val = 12 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 150000000UL ; FmaxBin = 200000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x0) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x2) ; divider_val = 8 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 200000000UL ; FmaxBin = 300000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x8) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x3) ; divider_val = 6 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 300000000UL ; FmaxBin = 400000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x0) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x3) ; divider_val = 4 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 400000000UL ; FmaxBin = 600000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x8) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x7) ; divider_val = 3 ; Fmax = FmaxBin ; Fmin = FminBin ; } FminBin = 600000000UL ; FmaxBin = 900000000UL ; if (state->TG_LO > FminBin && state->TG_LO <= FmaxBin) { status += MXL_ControlWrite(fe, TG_LO_DIVVAL, 0x0) ; status += MXL_ControlWrite(fe, TG_LO_SELVAL, 0x7) ; divider_val = 2 ; Fmax = FmaxBin ; Fmin = FminBin ; } // TG_DIV_VAL tg_divval = (state->TG_LO*divider_val/100000) *(MXL_Ceiling(state->Fxtal,1000000) * 100) / (state->Fxtal/1000) ; status += MXL_ControlWrite(fe, TG_DIV_VAL, tg_divval) ; if (state->TG_LO > 600000000UL) status += MXL_ControlWrite(fe, TG_DIV_VAL, tg_divval + 1 ) ; Fmax = 1800000000UL ; Fmin = 1200000000UL ; // to prevent overflow of 32 bit unsigned integer, use following equation. Edit for v2.6.4 Fref_TG = (state->Fxtal/1000)/ MXL_Ceiling(state->Fxtal, 1000000) ; // Fref_TF = Fref_TG*1000 Fvco = (state->TG_LO/10000) * divider_val * Fref_TG; //Fvco = Fvco/10 tg_lo = (((Fmax/10 - Fvco)/100)*32) / ((Fmax-Fmin)/1000)+8; //below equation is same as above but much harder to debug. //tg_lo = ( ((Fmax/10000 * Xtal_Int)/100) - ((state->TG_LO/10000)*divider_val*(state->Fxtal/10000)/100) )*32/((Fmax-Fmin)/10000 * Xtal_Int/100) + 8 ; status += MXL_ControlWrite(fe, TG_VCO_BIAS , tg_lo) ; //add for 2.6.5 //Special setting for QAM if(state->Mod_Type == MXL_QAM) { if(state->RF_IN < 680000000) status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 3) ; else status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 2) ; } //remove 20.48MHz setting for 2.6.10 // // Off Chip Tracking Filter Control // if (state->TF_Type == MXL_TF_OFF) // Tracking Filter Off State; turn off all the banks { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; status += MXL_SetGPIO(fe, 3, 1) ; // turn off Bank 1 status += MXL_SetGPIO(fe, 1, 1) ; // turn off Bank 2 status += MXL_SetGPIO(fe, 4, 1) ; // turn off Bank 3 } if (state->TF_Type == MXL_TF_C) // Tracking Filter type C { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; status += MXL_ControlWrite(fe, DAC_DIN_A, 0) ; if (state->RF_IN >= 43000000 && state->RF_IN < 150000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; status += MXL_SetGPIO(fe, 3, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank3 Off } if (state->RF_IN >= 150000000 && state->RF_IN < 280000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank3 Off } if (state->RF_IN >= 280000000 && state->RF_IN < 360000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 4, 0) ; // Bank3 On } if (state->RF_IN >= 360000000 && state->RF_IN < 560000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank3 On } if (state->RF_IN >= 560000000 && state->RF_IN < 580000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_ControlWrite(fe, DAC_DIN_B, 29) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank3 On } if (state->RF_IN >= 580000000 && state->RF_IN < 630000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank3 On } if (state->RF_IN >= 630000000 && state->RF_IN < 700000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_ControlWrite(fe, DAC_DIN_B, 16) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank3 Off } if (state->RF_IN >= 700000000 && state->RF_IN < 760000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_ControlWrite(fe, DAC_DIN_B, 7) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank3 Off } if (state->RF_IN >= 760000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; status += MXL_SetGPIO(fe, 3, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank3 Off } } if (state->TF_Type == MXL_TF_C_H) // Tracking Filter type C-H for Hauppauge only { printk("%s() CH filter\n", __func__); status += MXL_ControlWrite(fe, DAC_DIN_A, 0) ; if (state->RF_IN >= 43000000 && state->RF_IN < 150000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank3 Off } if (state->RF_IN >= 150000000 && state->RF_IN < 280000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank3 Off } if (state->RF_IN >= 280000000 && state->RF_IN < 360000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank3 On } if (state->RF_IN >= 360000000 && state->RF_IN < 560000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank3 On } if (state->RF_IN >= 560000000 && state->RF_IN < 580000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank3 On } if (state->RF_IN >= 580000000 && state->RF_IN < 630000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank3 On } if (state->RF_IN >= 630000000 && state->RF_IN < 700000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank3 Off } if (state->RF_IN >= 700000000 && state->RF_IN < 760000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank3 Off } if (state->RF_IN >= 760000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank3 Off } } if (state->TF_Type == MXL_TF_D) // Tracking Filter type D { status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; if (state->RF_IN >= 43000000 && state->RF_IN < 174000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 174000000 && state->RF_IN < 250000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 250000000 && state->RF_IN < 310000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 310000000 && state->RF_IN < 360000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 360000000 && state->RF_IN < 470000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 470000000 && state->RF_IN < 640000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 640000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } } if (state->TF_Type == MXL_TF_D_L) // Tracking Filter type D-L for Lumanate ONLY change for 2.6.3 { status += MXL_ControlWrite(fe, DAC_DIN_A, 0) ; // if UHF and terrestrial => Turn off Tracking Filter if (state->RF_IN >= 471000000 && (state->RF_IN - 471000000)%6000000 != 0) { // Turn off all the banks status += MXL_SetGPIO(fe, 3, 1) ; status += MXL_SetGPIO(fe, 1, 1) ; status += MXL_SetGPIO(fe, 4, 1) ; status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; status += MXL_ControlWrite(fe, AGC_IF, 10) ; } else // if VHF or cable => Turn on Tracking Filter { if (state->RF_IN >= 43000000 && state->RF_IN < 140000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 Off } if (state->RF_IN >= 140000000 && state->RF_IN < 240000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 Off } if (state->RF_IN >= 240000000 && state->RF_IN < 340000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 Off } if (state->RF_IN >= 340000000 && state->RF_IN < 430000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 On } if (state->RF_IN >= 430000000 && state->RF_IN < 470000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 On } if (state->RF_IN >= 470000000 && state->RF_IN < 570000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 On } if (state->RF_IN >= 570000000 && state->RF_IN < 620000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 0) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Offq } if (state->RF_IN >= 620000000 && state->RF_IN < 760000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 760000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_A_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } } } if (state->TF_Type == MXL_TF_E) // Tracking Filter type E { status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; if (state->RF_IN >= 43000000 && state->RF_IN < 174000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 174000000 && state->RF_IN < 250000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 250000000 && state->RF_IN < 310000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 310000000 && state->RF_IN < 360000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 360000000 && state->RF_IN < 470000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 470000000 && state->RF_IN < 640000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 640000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } } if (state->TF_Type == MXL_TF_F) // Tracking Filter type F { status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; if (state->RF_IN >= 43000000 && state->RF_IN < 160000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 160000000 && state->RF_IN < 210000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 210000000 && state->RF_IN < 300000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 300000000 && state->RF_IN < 390000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 390000000 && state->RF_IN < 515000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 515000000 && state->RF_IN < 650000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 650000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } } if (state->TF_Type == MXL_TF_E_2) // Tracking Filter type E_2 { status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; if (state->RF_IN >= 43000000 && state->RF_IN < 174000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 174000000 && state->RF_IN < 250000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 250000000 && state->RF_IN < 350000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 350000000 && state->RF_IN < 400000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 400000000 && state->RF_IN < 570000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 570000000 && state->RF_IN < 770000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 770000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } } if (state->TF_Type == MXL_TF_G) // Tracking Filter type G add for v2.6.8 { status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; if (state->RF_IN >= 50000000 && state->RF_IN < 190000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 190000000 && state->RF_IN < 280000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 280000000 && state->RF_IN < 350000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 350000000 && state->RF_IN < 400000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 400000000 && state->RF_IN < 470000000) //modified for 2.6.11 { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 470000000 && state->RF_IN < 640000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 640000000 && state->RF_IN < 820000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 820000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } } if (state->TF_Type == MXL_TF_E_NA) // Tracking Filter type E-NA for Empia ONLY change for 2.6.8 { status += MXL_ControlWrite(fe, DAC_DIN_B, 0) ; // if UHF and terrestrial=> Turn off Tracking Filter if (state->RF_IN >= 471000000 && (state->RF_IN - 471000000)%6000000 != 0) { // Turn off all the banks status += MXL_SetGPIO(fe, 3, 1) ; status += MXL_SetGPIO(fe, 1, 1) ; status += MXL_SetGPIO(fe, 4, 1) ; status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; //2.6.12 //Turn on RSSI status += MXL_ControlWrite(fe, SEQ_EXTSYNTHCALIF, 1) ; status += MXL_ControlWrite(fe, SEQ_EXTDCCAL, 1) ; status += MXL_ControlWrite(fe, AGC_EN_RSSI, 1) ; status += MXL_ControlWrite(fe, RFA_ENCLKRFAGC, 1) ; // RSSI reference point status += MXL_ControlWrite(fe, RFA_RSSI_REFH, 5) ; status += MXL_ControlWrite(fe, RFA_RSSI_REF, 3) ; status += MXL_ControlWrite(fe, RFA_RSSI_REFL, 2) ; //status += MXL_ControlWrite(fe, AGC_IF, 10) ; //doesn't matter since RSSI is turn on //following parameter is from analog OTA mode, can be change to seek better performance status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 3) ; } else //if VHF or Cable => Turn on Tracking Filter { //2.6.12 //Turn off RSSI status += MXL_ControlWrite(fe, AGC_EN_RSSI, 0) ; //change back from above condition status += MXL_ControlWrite(fe, RFSYN_CHP_GAIN, 5) ; if (state->RF_IN >= 43000000 && state->RF_IN < 174000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 174000000 && state->RF_IN < 250000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 0) ; // Bank1 On status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 250000000 && state->RF_IN < 350000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } if (state->RF_IN >= 350000000 && state->RF_IN < 400000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 0) ; // Bank2 On status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 400000000 && state->RF_IN < 570000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 0) ; // Bank4 Off status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 570000000 && state->RF_IN < 770000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 0) ; // Bank3 On } if (state->RF_IN >= 770000000 && state->RF_IN <= 900000000) { status += MXL_ControlWrite(fe, DAC_B_ENABLE, 1) ; // Bank4 On status += MXL_SetGPIO(fe, 4, 1) ; // Bank1 Off status += MXL_SetGPIO(fe, 1, 1) ; // Bank2 Off status += MXL_SetGPIO(fe, 3, 1) ; // Bank3 Off } } } return status ; } u16 MXL_SetGPIO(struct dvb_frontend *fe, u8 GPIO_Num, u8 GPIO_Val) { u16 status = 0; if (GPIO_Num == 1) status += MXL_ControlWrite(fe, GPIO_1B, GPIO_Val ? 0 : 1); /* GPIO2 is not available */ if (GPIO_Num == 3) { if (GPIO_Val == 1) { status += MXL_ControlWrite(fe, GPIO_3, 0); status += MXL_ControlWrite(fe, GPIO_3B, 0); } if (GPIO_Val == 0) { status += MXL_ControlWrite(fe, GPIO_3, 1); status += MXL_ControlWrite(fe, GPIO_3B, 1); } if (GPIO_Val == 3) { /* tri-state */ status += MXL_ControlWrite(fe, GPIO_3, 0); status += MXL_ControlWrite(fe, GPIO_3B, 1); } } if (GPIO_Num == 4) { if (GPIO_Val == 1) { status += MXL_ControlWrite(fe, GPIO_4, 0); status += MXL_ControlWrite(fe, GPIO_4B, 0); } if (GPIO_Val == 0) { status += MXL_ControlWrite(fe, GPIO_4, 1); status += MXL_ControlWrite(fe, GPIO_4B, 1); } if (GPIO_Val == 3) { /* tri-state */ status += MXL_ControlWrite(fe, GPIO_4, 0); status += MXL_ControlWrite(fe, GPIO_4B, 1); } } return status; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_ControlWrite // // // // Description: Update control name value // // // // Globals: // // NONE // // // // Functions used: // // MXL_ControlWrite( Tuner, controlName, value, Group ) // // // // Inputs: // // Tuner : Tuner structure // // ControlName : Control name to be updated // // value : Value to be written // // // // Outputs: // // Tuner : Tuner structure defined at higher level // // // // Return: // // 0 : Successful write // // >0 : Value exceed maximum allowed for control number // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_ControlWrite(struct dvb_frontend *fe, u16 ControlNum, u32 value) { u16 status = 0; /* Will write ALL Matching Control Name */ status += MXL_ControlWrite_Group(fe, ControlNum, value, 1); /* Write Matching INIT Control */ status += MXL_ControlWrite_Group(fe, ControlNum, value, 2); /* Write Matching CH Control */ #ifdef _MXL_INTERNAL status += MXL_ControlWrite_Group(fe, ControlNum, value, 3); /* Write Matching MXL Control */ #endif return status; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_ControlWrite // // // // Description: Update control name value // // // // Globals: // // NONE // // // // Functions used: // // strcmp // // // // Inputs: // // Tuner_struct: structure defined at higher level // // ControlName : Control Name // // value : Value Assigned to Control Name // // controlGroup : Control Register Group // // // // Outputs: // // NONE // // // // Return: // // 0 : Successful write // // 1 : Value exceed maximum allowed for control name // // 2 : Control name not found // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_ControlWrite_Group(struct dvb_frontend *fe, u16 controlNum, u32 value, u16 controlGroup) { struct mxl5005s_state *state = fe->tuner_priv; u16 i, j, k; u32 highLimit; u32 ctrlVal; if (controlGroup == 1) /* Initial Control */ { for (i = 0; i < state->Init_Ctrl_Num; i++) { if (controlNum == state->Init_Ctrl[i].Ctrl_Num) { highLimit = 1 << state->Init_Ctrl[i].size; if (value < highLimit) { for (j = 0; j < state->Init_Ctrl[i].size; j++) { state->Init_Ctrl[i].val[j] = (u8)((value >> j) & 0x01); MXL_RegWriteBit(fe, (u8)(state->Init_Ctrl[i].addr[j]), (u8)(state->Init_Ctrl[i].bit[j]), (u8)((value>>j) & 0x01) ); } ctrlVal = 0; for (k = 0; k < state->Init_Ctrl[i].size; k++) ctrlVal += state->Init_Ctrl[i].val[k] * (1 << k); } else return -1; } } } if (controlGroup == 2) /* Chan change Control */ { for (i = 0; i < state->CH_Ctrl_Num; i++) { if (controlNum == state->CH_Ctrl[i].Ctrl_Num ) { highLimit = 1 << state->CH_Ctrl[i].size; if (value < highLimit) { for (j = 0; j < state->CH_Ctrl[i].size; j++) { state->CH_Ctrl[i].val[j] = (u8)((value >> j) & 0x01); MXL_RegWriteBit(fe, (u8)(state->CH_Ctrl[i].addr[j]), (u8)(state->CH_Ctrl[i].bit[j]), (u8)((value>>j) & 0x01) ); } ctrlVal = 0; for (k = 0; k < state->CH_Ctrl[i].size; k++) ctrlVal += state->CH_Ctrl[i].val[k] * (1 << k); } else return -1; } } } #ifdef _MXL_INTERNAL if (controlGroup == 3) /* Maxlinear Control */ { for (i = 0; i < state->MXL_Ctrl_Num; i++) { if (controlNum == state->MXL_Ctrl[i].Ctrl_Num ) { highLimit = (1 << state->MXL_Ctrl[i].size) ; if (value < highLimit) { for (j = 0; j < state->MXL_Ctrl[i].size; j++) { state->MXL_Ctrl[i].val[j] = (u8)((value >> j) & 0x01); MXL_RegWriteBit(fe, (u8)(state->MXL_Ctrl[i].addr[j]), (u8)(state->MXL_Ctrl[i].bit[j]), (u8)((value>>j) & 0x01) ); } ctrlVal = 0; for(k = 0; k < state->MXL_Ctrl[i].size; k++) ctrlVal += state->MXL_Ctrl[i].val[k] * (1 << k); } else return -1; } } } #endif return 0 ; /* successful return */ } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_RegWrite // // // // Description: Update tuner register value // // // // Globals: // // NONE // // // // Functions used: // // NONE // // // // Inputs: // // Tuner_struct: structure defined at higher level // // RegNum : Register address to be assigned a value // // RegVal : Register value to write // // // // Outputs: // // NONE // // // // Return: // // 0 : Successful write // // -1 : Invalid Register Address // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_RegWrite(struct dvb_frontend *fe, u8 RegNum, u8 RegVal) { struct mxl5005s_state *state = fe->tuner_priv; int i ; for (i = 0; i < 104; i++) { if (RegNum == state->TunerRegs[i].Reg_Num) { state->TunerRegs[i].Reg_Val = RegVal; return 0; } } return 1; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_RegRead // // // // Description: Retrieve tuner register value // // // // Globals: // // NONE // // // // Functions used: // // NONE // // // // Inputs: // // Tuner_struct: structure defined at higher level // // RegNum : Register address to be assigned a value // // // // Outputs: // // RegVal : Retrieved register value // // // // Return: // // 0 : Successful read // // -1 : Invalid Register Address // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_RegRead(struct dvb_frontend *fe, u8 RegNum, u8 *RegVal) { struct mxl5005s_state *state = fe->tuner_priv; int i ; for (i = 0; i < 104; i++) { if (RegNum == state->TunerRegs[i].Reg_Num ) { *RegVal = (u8)(state->TunerRegs[i].Reg_Val); return 0; } } return 1; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_ControlRead // // // // Description: Retrieve the control value based on the control name // // // // Globals: // // NONE // // // // Inputs: // // Tuner_struct : structure defined at higher level // // ControlName : Control Name // // // // Outputs: // // value : returned control value // // // // Return: // // 0 : Successful read // // -1 : Invalid control name // // // /////////////////////////////////////////////////////////////////////////////// u16 MXL_ControlRead(struct dvb_frontend *fe, u16 controlNum, u32 *value) { struct mxl5005s_state *state = fe->tuner_priv; u32 ctrlVal ; u16 i, k ; for (i = 0; i < state->Init_Ctrl_Num ; i++) { if (controlNum == state->Init_Ctrl[i].Ctrl_Num) { ctrlVal = 0; for (k = 0; k < state->Init_Ctrl[i].size; k++) ctrlVal += state->Init_Ctrl[i].val[k] * (1 << k); *value = ctrlVal; return 0; } } for (i = 0; i < state->CH_Ctrl_Num ; i++) { if (controlNum == state->CH_Ctrl[i].Ctrl_Num) { ctrlVal = 0; for (k = 0; k < state->CH_Ctrl[i].size; k++) ctrlVal += state->CH_Ctrl[i].val[k] * (1 << k); *value = ctrlVal; return 0; } } #ifdef _MXL_INTERNAL for (i = 0; i < state->MXL_Ctrl_Num ; i++) { if (controlNum == state->MXL_Ctrl[i].Ctrl_Num) { ctrlVal = 0; for (k = 0; k < state->MXL_Ctrl[i].size; k++) ctrlVal += state->MXL_Ctrl[i].val[k] * (1<tuner_priv; u16 i, j, k ; u16 Count ; for (i = 0; i < state->Init_Ctrl_Num ; i++) { if ( controlNum == state->Init_Ctrl[i].Ctrl_Num ) { Count = 1; RegNum[0] = (u8)(state->Init_Ctrl[i].addr[0]); for (k = 1; k < state->Init_Ctrl[i].size; k++) { for (j = 0; j < Count; j++) { if (state->Init_Ctrl[i].addr[k] != RegNum[j]) { Count ++; RegNum[Count-1] = (u8)(state->Init_Ctrl[i].addr[k]); } } } *count = Count; return 0; } } for (i = 0; i < state->CH_Ctrl_Num ; i++) { if ( controlNum == state->CH_Ctrl[i].Ctrl_Num ) { Count = 1; RegNum[0] = (u8)(state->CH_Ctrl[i].addr[0]); for (k = 1; k < state->CH_Ctrl[i].size; k++) { for (j= 0; jCH_Ctrl[i].addr[k] != RegNum[j]) { Count ++; RegNum[Count-1] = (u8)(state->CH_Ctrl[i].addr[k]); } } } *count = Count; return 0; } } #ifdef _MXL_INTERNAL for (i = 0; i < state->MXL_Ctrl_Num ; i++) { if ( controlNum == state->MXL_Ctrl[i].Ctrl_Num ) { Count = 1; RegNum[0] = (u8)(state->MXL_Ctrl[i].addr[0]); for (k = 1; k < state->MXL_Ctrl[i].size; k++) { for (j = 0; jMXL_Ctrl[i].addr[k] != RegNum[j]) { Count ++; RegNum[Count-1] = (u8)state->MXL_Ctrl[i].addr[k]; } } } *count = Count; return 0; } } #endif *count = 0; return 1; } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_RegWriteBit // // // // Description: Write a register for specified register address, // // register bit and register bit value // // // // Globals: // // NONE // // // // Inputs: // // Tuner_struct : structure defined at higher level // // address : register address // // bit : register bit number // // bitVal : register bit value // // // // Outputs: // // NONE // // // // Return: // // NONE // // // /////////////////////////////////////////////////////////////////////////////// void MXL_RegWriteBit(struct dvb_frontend *fe, u8 address, u8 bit, u8 bitVal) { struct mxl5005s_state *state = fe->tuner_priv; int i ; const u8 AND_MAP[8] = { 0xFE, 0xFD, 0xFB, 0xF7, 0xEF, 0xDF, 0xBF, 0x7F } ; const u8 OR_MAP[8] = { 0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80 } ; for (i = 0; i < state->TunerRegs_Num; i++) { if (state->TunerRegs[i].Reg_Num == address) { if (bitVal) state->TunerRegs[i].Reg_Val |= OR_MAP[bit]; else state->TunerRegs[i].Reg_Val &= AND_MAP[bit]; break ; } } } /////////////////////////////////////////////////////////////////////////////// // // // Function: MXL_Ceiling // // // // Description: Complete to closest increment of resolution // // // // Globals: // // NONE // // // // Functions used: // // NONE // // // // Inputs: // // value : Input number to compute // // resolution : Increment step // // // // Outputs: // // NONE // // // // Return: // // Computed value // // // /////////////////////////////////////////////////////////////////////////////// u32 MXL_Ceiling(u32 value, u32 resolution) { return (value/resolution + (value % resolution > 0 ? 1 : 0)); } // // Retrieve the Initialzation Registers // u16 MXL_GetInitRegister(struct dvb_frontend *fe, u8 * RegNum, u8 *RegVal, int *count) { u16 status = 0; int i ; u8 RegAddr[] = { 11, 12, 13, 22, 32, 43, 44, 53, 56, 59, 73, 76, 77, 91, 134, 135, 137, 147, 156, 166, 167, 168, 25 }; *count = sizeof(RegAddr) / sizeof(u8); status += MXL_BlockInit(fe); for (i = 0 ; i < *count; i++) { RegNum[i] = RegAddr[i]; status += MXL_RegRead(fe, RegNum[i], &RegVal[i]); } return status; } u16 MXL_GetCHRegister(struct dvb_frontend *fe, u8 * RegNum, u8 *RegVal, int *count) { u16 status = 0; int i ; //add 77, 166, 167, 168 register for 2.6.12 #ifdef _MXL_PRODUCTION u8 RegAddr[] = {14, 15, 16, 17, 22, 43, 65, 68, 69, 70, 73, 92, 93, 106, 107, 108, 109, 110, 111, 112, 136, 138, 149, 77, 166, 167, 168 } ; #else u8 RegAddr[] = {14, 15, 16, 17, 22, 43, 68, 69, 70, 73, 92, 93, 106, 107, 108, 109, 110, 111, 112, 136, 138, 149, 77, 166, 167, 168 } ; //u8 RegAddr[171]; //for (i=0; i<=170; i++) // RegAddr[i] = i; #endif *count = sizeof(RegAddr) / sizeof(u8); for (i = 0 ; i < *count; i++) { RegNum[i] = RegAddr[i]; status += MXL_RegRead(fe, RegNum[i], &RegVal[i]); } return status; } u16 MXL_GetCHRegister_ZeroIF(struct dvb_frontend *fe, u8 * RegNum, u8 *RegVal, int *count) { u16 status = 0; int i; u8 RegAddr[] = {43, 136}; *count = sizeof(RegAddr) / sizeof(u8); for (i = 0; i < *count; i++) { RegNum[i] = RegAddr[i]; status += MXL_RegRead(fe, RegNum[i], &RegVal[i]); } return status; } u16 MXL_GetCHRegister_LowIF(struct dvb_frontend *fe, u8 * RegNum, u8 *RegVal, int *count) { u16 status = 0; int i; u8 RegAddr[] = { 138 }; *count = sizeof(RegAddr) / sizeof(u8); for (i = 0; i < *count; i++) { RegNum[i] = RegAddr[i]; status += MXL_RegRead(fe, RegNum[i], &RegVal[i]); } return status; } u16 MXL_GetMasterControl(u8 *MasterReg, int state) { if (state == 1) /* Load_Start */ *MasterReg = 0xF3; if (state == 2) /* Power_Down */ *MasterReg = 0x41; if (state == 3) /* Synth_Reset */ *MasterReg = 0xB1; if (state == 4) /* Seq_Off */ *MasterReg = 0xF1; return 0; } #ifdef _MXL_PRODUCTION u16 MXL_VCORange_Test(struct dvb_frontend *fe, int VCO_Range) { struct mxl5005s_state *state = fe->tuner_priv; u16 status = 0 ; if (VCO_Range == 1) { status += MXL_ControlWrite(fe, RFSYN_EN_DIV, 1); status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0); status += MXL_ControlWrite(fe, RFSYN_DIVM, 1); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1); status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1); status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0); if (state->Mode == 0 && state->IF_Mode == 1) /* Analog Low IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 8); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 56); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 180224); } if (state->Mode == 0 && state->IF_Mode == 0) /* Analog Zero IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 8); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 56); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 222822); } if (state->Mode == 1) /* Digital Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 8); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 56); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 229376); } } if (VCO_Range == 2) { status += MXL_ControlWrite(fe, RFSYN_EN_DIV, 1); status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0); status += MXL_ControlWrite(fe, RFSYN_DIVM, 1); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1); status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1); status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 41); if (state->Mode == 0 && state->IF_Mode == 1) /* Analog Low IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 42); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 206438); } if (state->Mode == 0 && state->IF_Mode == 0) /* Analog Zero IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 42); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 206438); } if (state->Mode == 1) /* Digital Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 1); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 41); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 16384); } } if (VCO_Range == 3) { status += MXL_ControlWrite(fe, RFSYN_EN_DIV, 1); status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0); status += MXL_ControlWrite(fe, RFSYN_DIVM, 1); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1); status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1); status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 8); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 42); if (state->Mode == 0 && state->IF_Mode == 1) /* Analog Low IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 8); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 44); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 173670); } if (state->Mode == 0 && state->IF_Mode == 0) /* Analog Zero IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 8); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 44); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 173670); } if (state->Mode == 1) /* Digital Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 8); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 42); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 245760); } } if (VCO_Range == 4) { status += MXL_ControlWrite(fe, RFSYN_EN_DIV, 1); status += MXL_ControlWrite(fe, RFSYN_EN_OUTMUX, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_DIVM, 0); status += MXL_ControlWrite(fe, RFSYN_DIVM, 1); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_OUT, 1); status += MXL_ControlWrite(fe, RFSYN_RF_DIV_BIAS, 1); status += MXL_ControlWrite(fe, DN_SEL_FREQ, 0); status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 27); if (state->Mode == 0 && state->IF_Mode == 1) /* Analog Low IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 27); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 206438); } if (state->Mode == 0 && state->IF_Mode == 0) /* Analog Zero IF Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 27); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 206438); } if (state->Mode == 1) /* Digital Mode */ { status += MXL_ControlWrite(fe, RFSYN_SEL_VCO_HI, 0); status += MXL_ControlWrite(fe, RFSYN_VCO_BIAS, 40); status += MXL_ControlWrite(fe, CHCAL_INT_MOD_RF, 27); status += MXL_ControlWrite(fe, CHCAL_FRAC_MOD_RF, 212992); } } return status; } u16 MXL_Hystersis_Test(struct dvb_frontend *fe, int Hystersis) { struct mxl5005s_state *state = fe->tuner_priv; u16 status = 0; if (Hystersis == 1) status += MXL_ControlWrite(fe, DN_BYPASS_AGC_I2C, 1); return status; } #endif /* End: Reference driver code found in the Realtek driver that * is copyright MaxLinear */ /* ---------------------------------------------------------------- * Begin: Everything after here is new code to adapt the * proprietary Realtek driver into a Linux API tuner. * Copyright (C) 2008 Steven Toth */ static int mxl5005s_reset(struct dvb_frontend *fe) { struct mxl5005s_state *state = fe->tuner_priv; int ret = 0; u8 buf[2] = { 0xff, 0x00 }; struct i2c_msg msg = { .addr = state->config->i2c_address, .flags = 0, .buf = buf, .len = 2 }; dprintk(2, "%s()\n", __func__); if (fe->ops.i2c_gate_ctrl) fe->ops.i2c_gate_ctrl(fe, 1); if (i2c_transfer(state->i2c, &msg, 1) != 1) { printk(KERN_WARNING "mxl5005s I2C reset failed\n"); ret = -EREMOTEIO; } if (fe->ops.i2c_gate_ctrl) fe->ops.i2c_gate_ctrl(fe, 0); return ret; } /* Write a single byte to a single reg, latch the value if required by * following the transaction with the latch byte. */ static int mxl5005s_writereg(struct dvb_frontend *fe, u8 reg, u8 val, int latch) { struct mxl5005s_state *state = fe->tuner_priv; u8 buf[3] = { reg, val, MXL5005S_LATCH_BYTE }; struct i2c_msg msg = { .addr = state->config->i2c_address, .flags = 0, .buf = buf, .len = 3 }; if (latch == 0) msg.len = 2; dprintk(2, "%s(reg = 0x%x val = 0x%x addr = 0x%x)\n", __func__, reg, val, msg.addr); if (i2c_transfer(state->i2c, &msg, 1) != 1) { printk(KERN_WARNING "mxl5005s I2C write failed\n"); return -EREMOTEIO; } return 0; } int mxl5005s_writeregs(struct dvb_frontend *fe, u8 *addrtable, u8 *datatable, u8 len) { int ret = 0, i; if (fe->ops.i2c_gate_ctrl) fe->ops.i2c_gate_ctrl(fe, 1); for (i = 0 ; i < len-1; i++) { ret = mxl5005s_writereg(fe, addrtable[i], datatable[i], 0); if (ret < 0) break; } ret = mxl5005s_writereg(fe, addrtable[i], datatable[i], 1); if (fe->ops.i2c_gate_ctrl) fe->ops.i2c_gate_ctrl(fe, 0); return ret; } int mxl5005s_init(struct dvb_frontend *fe) { dprintk(1, "%s()\n", __func__); return mxl5005s_reconfigure(fe, MXL_QAM, MXL5005S_BANDWIDTH_6MHZ); } int mxl5005s_reconfigure(struct dvb_frontend *fe, u32 mod_type, u32 bandwidth) { struct mxl5005s_state *state = fe->tuner_priv; u8 AddrTable[MXL5005S_REG_WRITING_TABLE_LEN_MAX]; u8 ByteTable[MXL5005S_REG_WRITING_TABLE_LEN_MAX]; int TableLen; dprintk(1, "%s(type=%d, bw=%d)\n", __func__, mod_type, bandwidth); mxl5005s_reset(fe); /* Tuner initialization stage 0 */ MXL_GetMasterControl(ByteTable, MC_SYNTH_RESET); AddrTable[0] = MASTER_CONTROL_ADDR; ByteTable[0] |= state->config->AgcMasterByte; mxl5005s_writeregs(fe, AddrTable, ByteTable, 1); mxl5005s_AssignTunerMode(fe, mod_type, bandwidth); /* Tuner initialization stage 1 */ MXL_GetInitRegister(fe, AddrTable, ByteTable, &TableLen); mxl5005s_writeregs(fe, AddrTable, ByteTable, TableLen); return 0; } int mxl5005s_AssignTunerMode(struct dvb_frontend *fe, u32 mod_type, u32 bandwidth) { struct mxl5005s_state *state = fe->tuner_priv; struct mxl5005s_config *c = state->config; InitTunerControls(fe); /* Set MxL5005S parameters. */ MXL5005_TunerConfig( fe, c->mod_mode, c->if_mode, bandwidth, c->if_freq, c->xtal_freq, c->agc_mode, c->top, c->output_load, c->clock_out, c->div_out, c->cap_select, c->rssi_enable, mod_type, c->tracking_filter); return 0; } static int mxl5005s_set_params(struct dvb_frontend *fe, struct dvb_frontend_parameters *params) { struct mxl5005s_state *state = fe->tuner_priv; u32 req_mode, req_bw = 0; int ret; dprintk(1, "%s()\n", __func__); if (fe->ops.info.type == FE_ATSC) { switch (params->u.vsb.modulation) { case VSB_8: req_mode = MXL_ATSC; break; default: case QAM_64: case QAM_256: case QAM_AUTO: req_mode = MXL_QAM; break; } } else req_mode = MXL_DVBT; /* Change tuner for new modulation type if reqd */ if (req_mode != state->current_mode) { switch (req_mode) { case VSB_8: case QAM_64: case QAM_256: case QAM_AUTO: req_bw = MXL5005S_BANDWIDTH_6MHZ; break; default: /* Assume DVB-T */ switch (params->u.ofdm.bandwidth) { case BANDWIDTH_6_MHZ: req_bw = MXL5005S_BANDWIDTH_6MHZ; break; case BANDWIDTH_7_MHZ: req_bw = MXL5005S_BANDWIDTH_7MHZ; break; case BANDWIDTH_AUTO: case BANDWIDTH_8_MHZ: req_bw = MXL5005S_BANDWIDTH_8MHZ; break; } } state->current_mode = req_mode; ret = mxl5005s_reconfigure(fe, req_mode, req_bw); } else ret = 0; if (ret == 0) { dprintk(1, "%s() freq=%d\n", __func__, params->frequency); ret = mxl5005s_SetRfFreqHz(fe, params->frequency); } return ret; } static int mxl5005s_get_frequency(struct dvb_frontend *fe, u32 *frequency) { struct mxl5005s_state *state = fe->tuner_priv; dprintk(1, "%s()\n", __func__); *frequency = state->RF_IN; return 0; } static int mxl5005s_get_bandwidth(struct dvb_frontend *fe, u32 *bandwidth) { struct mxl5005s_state *state = fe->tuner_priv; dprintk(1, "%s()\n", __func__); *bandwidth = state->Chan_Bandwidth; return 0; } static int mxl5005s_release(struct dvb_frontend *fe) { dprintk(1, "%s()\n", __func__); kfree(fe->tuner_priv); fe->tuner_priv = NULL; return 0; } static const struct dvb_tuner_ops mxl5005s_tuner_ops = { .info = { .name = "MaxLinear MXL5005S", .frequency_min = 48000000, .frequency_max = 860000000, .frequency_step = 50000, }, .release = mxl5005s_release, .init = mxl5005s_init, .set_params = mxl5005s_set_params, .get_frequency = mxl5005s_get_frequency, .get_bandwidth = mxl5005s_get_bandwidth, }; struct dvb_frontend *mxl5005s_attach(struct dvb_frontend *fe, struct i2c_adapter *i2c, struct mxl5005s_config *config) { struct mxl5005s_state *state = NULL; dprintk(1, "%s()\n", __func__); state = kzalloc(sizeof(struct mxl5005s_state), GFP_KERNEL); if (state == NULL) return NULL; state->frontend = fe; state->config = config; state->i2c = i2c; state->current_mode = MXL_QAM; printk(KERN_INFO "MXL5005S: Attached at address 0x%02x\n", config->i2c_address); memcpy(&fe->ops.tuner_ops, &mxl5005s_tuner_ops, sizeof(struct dvb_tuner_ops)); fe->tuner_priv = state; return fe; } EXPORT_SYMBOL(mxl5005s_attach); MODULE_DESCRIPTION("MaxLinear MXL5005S silicon tuner driver"); MODULE_AUTHOR("Steven Toth"); MODULE_LICENSE("GPL");