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MStar hereby reserves the // rights to any and all damages, losses, costs and expenses resulting therefrom. // //////////////////////////////////////////////////////////////////////////////// //////////////////////////////////////////////////////////////////////////////// // /// @file INTERN_DVBT.c /// @brief INTERN_DVBT DVBT /// @author MStar Semiconductor, Inc. // //////////////////////////////////////////////////////////////////////////////// #define _INTERN_DVBT_C_ #include #include "MsCommon.h" #include "MsIRQ.h" #include "MsOS.h" //#include "apiPWS.h" #include "MsTypes.h" #include "drvBDMA.h" //#include "drvIIC.h" //#include "msAPI_Tuner.h" //#include "msAPI_MIU.h" //#include "BinInfo.h" //#include "halVif.h" #include "drvDMD_INTERN_DVBC.h" #include "halDMD_INTERN_DVBC.h" #include "halDMD_INTERN_common.h" #ifdef SUPPORT_AP_BIN_IN_FLASH_2 #include "InfoBlock.h" #endif #include "drvMMIO.h" //#include "TDAG4D01A_SSI_DVBT.c" #include "drvDMD_VD_MBX.h" #include "ULog.h" #define TEST_EMBEDED_DEMOD 0 //U8 load_data_variable=1; //----------------------------------------------------------------------- #define BIN_ID_INTERN_DVBC_DEMOD BIN_ID_INTERN_DVBC #define TDE_REG_BASE 0x2800UL #define INNC_REG_BASE 0x3800UL #define EQE_REG_BASE 0x3900UL //#define EQE2_REG_BASE 0x2d00UL #ifdef MS_DEBUG #define DBG_INTERN_DVBC(x) x #define DBG_GET_SIGNAL_DVBC(x) x #define DBG_INTERN_DVBC_TIME(x) x #define DBG_INTERN_DVBC_LOCK(x) x #define INTERN_DVBC_INTERNAL_DEBUG 0 #else #define DBG_INTERN_DVBC(x) //x #define DBG_GET_SIGNAL_DVBC(x) //x #define DBG_INTERN_DVBC_TIME(x) //x #define DBG_INTERN_DVBC_LOCK(x) //x #define INTERN_DVBC_INTERNAL_DEBUG 0 #endif #define DBG_DUMP_LOAD_DSP_TIME 0 #define SIGNAL_LEVEL_OFFSET 0.00f #define TAKEOVERPOINT -60.0f #define TAKEOVERRANGE 0.5f #define LOG10_OFFSET -0.21f #define INTERN_DVBC_USE_SAR_3_ENABLE 0 #define INTERN_DVBT_GET_TIME msAPI_Timer_GetTime0() #define TUNER_IF 5000 #define TS_SER_C 0x00 //0: parallel 1:serial #if (INTERN_DVBC_TS_SERIAL_INVERSION) #define TS_INV_C 0x01 #else #define TS_INV_C 0x00 #endif #define DVBC_FS 48000 //24000 #define CFG_ZIF 0x00 //For ZIF ,FC=0 #define FC_H_C ( (DVBC_FS-TUNER_IF)>0 ? (((DVBC_FS-TUNER_IF)>>8)&0xFF) : (((TUNER_IF-DVBC_FS)>>8)&0xFF) ) #define FC_L_C ( (DVBC_FS-TUNER_IF)>0 ? (((DVBC_FS-TUNER_IF))&0xFF) : (((TUNER_IF-DVBC_FS))&0xFF) ) #define FS_H_C ((DVBC_FS>>8)&0xFF) // FS #define FS_L_C (DVBC_FS&0xFF) #define AUTO_SCAN_C 0x00 // Auto Scan - 0:channel change, 1:auto-scan #define IQ_SWAP_C 0x00 #define PAL_I_C 0x00 // PAL_I: 0: Non-Pal-I CCI, 1: Pal-I CCI (for UK) // Bxko 6875, 6900, 7000, 6125, 4000, 6950 // Symbol Rate: 6875 = 0x1ADB // Symbol Rate: 6900 = 0x1AF4 // Symbol Rate: 7000 = 0x1B58 // Symbol Rate: 4000 = 0x0FA0 // Symbol Rate: 6125 = 0x17ED #define SR0_H 0x1A #define SR0_L 0xF4 //6900 #define SR1_H 0x1B #define SR1_L 0x58 //7000 #define SR2_H 0x17 #define SR2_L 0xED //6125 #define SR3_H 0x0F #define SR3_L 0xA0 //4000 #define SR4_H 0x1B #define SR4_L 0x26 //6950 #define SR5_H 0x1A //0xDB #define SR5_L 0xDB //0x1A //6875 #define SR6_H 0x1C #define SR6_L 0x20 //7200 #define SR7_H 0x1C #define SR7_L 0x52 //7250 #define SR8_H 0x0B #define SR8_L 0xB8 //3000 #define SR9_H 0x03 #define SR9_L 0xE8 //1000 #define SR10_H 0x07 #define SR10_L 0xD0 //2000 #define SR11_H 0x00 #define SR11_L 0x00 //0000 #define QAM 0x04 // QAM: 0:16, 1:32, 2:64, 3:128, 4:256 // SAR dependent #define NO_SIGNAL_TH_A 0xA3 // Tuner dependent #define NO_SIGNAL_TH_B_L 0xFF //0x00 , Gain #define NO_SIGNAL_TH_B_H 0xFF //0xDD #define NO_SIGNAL_TH_C_L 0xff //0x64 , Err #define NO_SIGNAL_TH_C_H 0xff //0x00 #define DAGC1_REF 0x70 #define DAGC2_REF 0x30 #define AGC_REF_L 0x00 #define AGC_REF_H 0x06 #define INTERN_AUTO_SR_C 1 #define INTERN_AUTO_QAM_C 1 #define ATV_DET_EN 1 // Need to update when: // Case#1: New add DSP parameters // Case#2: Use exist DSP parameters to another applications/functions #define UTOPIA_DRIVER_VERSION 0x01 // Update by user. #if 0 MS_U8 INTERN_DVBC_DSPREG[] = { 0x00, 0x00, 0x01, 0x00, 0x01, 0x00, 0x01, AUTO_SCAN_C, // 00h ~ 07h INTERN_AUTO_SR_C, INTERN_AUTO_QAM_C, ATV_DET_EN, NO_SIGNAL_TH_B_L, NO_SIGNAL_TH_B_H, NO_SIGNAL_TH_C_L, NO_SIGNAL_TH_C_H, 0x00, // 08h ~ 0fh 0x00, CFG_ZIF, 0x00, FC_L_C, FC_H_C, FS_L_C, FS_H_C, SR0_L, // 10h ~ 17h SR0_H, SR1_L, SR1_H, SR2_L, SR2_H, SR3_L, SR3_H, 0x00, // 18h ~ 1fh 0x00, QAM, IQ_SWAP_C, PAL_I_C, TS_SER_C, 0x00, TS_INV_C, 0x00, // 20h ~27h }; #else MS_U8 INTERN_DVBC_DSPREG[] = { 0x00, 0x00, 0x00, 0x01, 0x00, 0x01, 0x00, 0x01, AUTO_SCAN_C, INTERN_AUTO_SR_C, INTERN_AUTO_QAM_C, ATV_DET_EN, 0x00, 0x00, 0x01, 0x00, //00-0F 0x00, 0x00, CFG_ZIF, FS_L_C, FS_H_C, 0x88, 0x13, FC_L_C, FC_H_C, SR0_L, SR0_H, SR1_L, SR1_H, SR2_L, SR2_H, SR3_L, //10-1F SR3_H, SR4_L, SR4_H, SR5_L, SR5_H, SR6_L, SR6_H, SR7_L, SR7_H, SR8_L, SR8_H, SR9_L, SR9_H, SR10_L, SR10_H, SR11_L, //20-2F SR11_H, 0x00, QAM, IQ_SWAP_C, PAL_I_C, TS_SER_C, 0x00, TS_INV_C, 0x00, 0x00, AGC_REF_L, AGC_REF_H, 0x90, 0xa0, 0x03, 0x05, //30-3F 0x05, 0x40, 0x04, 0x13, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x80, 0x7F, 0x00, NO_SIGNAL_TH_B_L, NO_SIGNAL_TH_B_H, NO_SIGNAL_TH_C_L, //40-4F NO_SIGNAL_TH_C_H, 0x00, 0x00, 0x00, 0x00, 0x00, DAGC1_REF, DAGC2_REF, 0x73, 0x73, 0x73, 0x73, 0x73, 0x83, 0x83, 0x73, //50-5F 0x62, 0x62, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, //60-6C }; #endif #define TS_SERIAL_OUTPUT_IF_CI_REMOVED 1 // _UTOPIA //----------------------------------------------------------------------- /**************************************************************** *Local Variables * ****************************************************************/ //static MS_BOOL TPSLock = 0; static MS_U32 u32ChkScanTimeStartDVBC = 0; static MS_U8 g_dvbc_lock = 0; static float intern_dvb_c_qam_ref[] = {3.0, 0.0, 0.0, 0.0, 0.0, 80.0}; //16q,32q,64q,128q,256q, and others //Global Variables S_CMDPKTREG gsCmdPacketDVBC; //MS_U8 gCalIdacCh0, gCalIdacCh1; static MS_BOOL bDMD_DVBC_NoChannelDetectedWithRFPower = FALSE; static MS_U32 u32DMD_DVBC_NoChannelTimeAccWithRFPower = 0; #ifdef INTERN_DVBC_LOAD_FW_FROM_CODE_MEMORY MS_U8 INTERN_DVBC_table[] = { #include "fwDMD_INTERN_DVBC.dat" }; #endif MS_BOOL INTERN_DVBC_Show_Demod_Version(void); // MS_BOOL INTERN_DVBC_GetPostViterbiBer(float *ber); // MS_BOOL INTERN_DVBC_GetPacketErr(MS_U16 *pktErr); //MS_BOOL INTERN_DVBC_GetSNR(float *f_snr); // MS_BOOL INTERN_DVBC_Get_FreqOffset(float *pFreqOff); MS_BOOL INTERN_DVBC_GetCurrentModulationType(DMD_DVBC_MODULATION_TYPE *pQAMMode); MS_BOOL INTERN_DVBC_GetCurrentSymbolRate(MS_U16 *u16SymbolRate); MS_BOOL INTERN_DVBC_GetCurrentSymbolRateOffset(MS_U16 *pData); #if (INTERN_DVBC_INTERNAL_DEBUG) void INTERN_DVBC_info(void); MS_BOOL INTERN_DVBC_Show_AGC_Info(void); #endif MS_U16 INTERN_DVBC_DSPReg_Init(const MS_U8 *u8DVBC_DSPReg, MS_U8 u8Size) { MS_U8 idx = 0, u8RegRead = 0, u8RegWrite = 0, u8Mask = 0; MS_U8 status = TRUE; MS_U16 u16DspAddr = 0; ULOGD("DEMOD","INTERN_DVBC_DSPReg_Init\n"); #if 0//def MS_DEBUG { MS_U8 u8buffer[256]; ULOGD("DEMOD","INTERN_DVBC_DSPReg_Init Reset\n"); for (idx = 0; idxINTERN_DVBC (cmd=0x%x)(0x%x,0x%x,0x%x,0x%x,0x%x,0x%x,) \n",pCmdPacket->cmd_code, pCmdPacket->param[0],pCmdPacket->param[1], pCmdPacket->param[2],pCmdPacket->param[3], pCmdPacket->param[4],pCmdPacket->param[5] ); // wait _BIT_END clear do { reg_val = HAL_DMD_RIU_ReadByte(REG_CMD_CTRL); if((reg_val & _BIT_END) != _BIT_END) { break; } MsOS_DelayTask(5); if (timeout > 200) { ULOGD("DEMOD","---> INTERN_DVBC_Cmd_Packet_Send fail on 'wait _BIT_END clear' \n"); return false; } timeout++; } while (1); // set cmd_3:0 and _BIT_START reg_val = HAL_DMD_RIU_ReadByte(REG_CMD_CTRL); reg_val = (reg_val & 0x0f)|(pCmdPacket->cmd_code << 4)|_BIT_START; HAL_DMD_RIU_WriteByte(REG_CMD_CTRL, reg_val); //DBG_INTERN_DVBT(ULOGD("DEMOD","demod_config: cmd_code = %bx\n", pCmdPacket->cmd_code)); // wait _BIT_START clear do { reg_val = HAL_DMD_RIU_ReadByte(REG_CMD_CTRL); if((reg_val & _BIT_START) != _BIT_START) { break; } MsOS_DelayTask(10); if (timeout > 200) { ULOGD("DEMOD","---> INTERN_DVBC_Cmd_Packet_Send fail on 'wait _BIT_START clear' \n"); return false; } timeout++; } while (1); // ==== Data Phase ====================== HAL_DMD_RIU_WriteByte(REG_CMD_ADDR, 0x00); for (indx = 0; indx < param_cnt; indx++) { reg_val = HAL_DMD_RIU_ReadByte(REG_CMD_ADDR); //DBG_INTERN_DVBT(ULOGD("DEMOD","demod_config: param[%bd] = %bx\n", reg_val, pCmdPacket->param[indx])); // set param[indx] and _BIT_DRQ HAL_DMD_RIU_WriteByte(REG_CMD_DATA, pCmdPacket->param[indx]); reg_val = HAL_DMD_RIU_ReadByte(REG_DTA_CTRL); HAL_DMD_RIU_WriteByte(REG_DTA_CTRL, reg_val|_BIT_DRQ); // wait _BIT_DRQ clear do { reg_val = HAL_DMD_RIU_ReadByte(REG_DTA_CTRL); if ((reg_val & _BIT_DRQ) != _BIT_DRQ) { break; } MsOS_DelayTask(5); if (timeout > 200) { ULOGD("DEMOD","---> INTERN_DVBC_Cmd_Packet_Send fail on 'wait _BIT_DRQ clear' \n"); return false; } timeout++; } while (1); } // ==== End Phase ======================= // set _BIT_END to finish command reg_val = HAL_DMD_RIU_ReadByte(REG_CMD_CTRL); HAL_DMD_RIU_WriteByte(REG_CMD_CTRL, reg_val|_BIT_END); //MsOS_ReleaseMutex(_s32_Demod_DVBT_Mutex); return status; } /*********************************************************************************** Subject: Command Packet Interface Function: INTERN_DVBT_Cmd_Packet_Exe_Check Parmeter: Return: MS_BOOL Remark: ************************************************************************************/ MS_BOOL INTERN_DVBC_Cmd_Packet_Exe_Check(MS_BOOL* cmd_done) { return TRUE; } /*********************************************************************************** Subject: SoftStop Function: INTERN_DVBC_SoftStop Parmeter: Return: MS_BOOL Remark: ************************************************************************************/ MS_BOOL INTERN_DVBC_SoftStop ( void ) { #if 1 MS_U16 u8WaitCnt=0; if (HAL_DMD_RIU_ReadByte(MBRegBase + 0x00)) { ULOGD("DEMOD",">> MB Busy!\n"); return FALSE; } HAL_DMD_RIU_WriteByte(MBRegBase + 0x00, 0xA5); // MB_CNTL set read mode HAL_DMD_RIU_WriteByte(0x103483, 0x02); // assert interrupt to VD MCU51 HAL_DMD_RIU_WriteByte(0x103483, 0x00); // de-assert interrupt to VD MCU51 while(HAL_DMD_RIU_ReadByte(MBRegBase + 0x00)!= 0x5A) // wait MB_CNTL set done { #if TEST_EMBEDED_DEMOD MsOS_DelayTask(1); // << Ken 20090629 #endif if (u8WaitCnt++ >= 0xFF) { ULOGD("DEMOD",">> DVBT SoftStop Fail!\n"); return FALSE; } } //HAL_DMD_RIU_WriteByte(0x103460, 0x01); // reset VD_MCU HAL_DMD_RIU_WriteByte(MBRegBase + 0x00, 0x00); // MB_CNTL clear #endif return TRUE; } /*********************************************************************************** Subject: Reset Function: INTERN_DVBC_Reset Parmeter: Return: MS_BOOL Remark: ************************************************************************************/ extern void HAL_SYS_DMD_VD_MBX_DVB_WaitHandShake(void); MS_BOOL INTERN_DVBC_Reset ( void ) { ULOGD("DEMOD"," @INTERN_DVBC_reset\n"); //ULOGD("DEMOD","INTERN_DVBC_Reset, t = %ld\n",MsOS_GetSystemTime()); //INTERN_DVBC_SoftStop(); HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x00, 0x01); // reset DMD_MCU //MDrv_SYS_DMD_VD_MBX_WriteReg(0x2002, 0x72); // reset DVB-T MsOS_DelayTask(5); HAL_DMD_RIU_WriteByte(MBRegBase + 0x00 , 0x00); // clear MB_CNTL // MDrv_SYS_DMD_VD_MBX_WriteReg(0x2002, 0x52); HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x00, 0x00); MsOS_DelayTask(5); HAL_SYS_DMD_VD_MBX_DVB_WaitHandShake(); HAL_DMD_RIU_WriteByte(MBRegBase + 0x00 , 0x00); u32ChkScanTimeStartDVBC = MsOS_GetSystemTime(); g_dvbc_lock = 0; return TRUE; } /*********************************************************************************** Subject: Exit Function: INTERN_DVBC_Exit Parmeter: Return: MS_BOOL Remark: ************************************************************************************/ MS_BOOL INTERN_DVBC_Exit ( void ) { INTERN_DVBC_SoftStop(); //diable clk gen //HAL_DMD_RIU_WriteByte(0x103314, 0x01); // reg_ckg_dvbtc_adc@0x0a[3:0] : ADC_CLK //HAL_DMD_RIU_WriteByte(0x103315, 0x01); // reg_ckg_dvbtc_innc@0x0a[11:8] HAL_DMD_RIU_WriteByte(0x10330a, 0x01); // reg_ckg_atsc_adcd_sync@0x05[3:0] : ADCCLK HAL_DMD_RIU_WriteByte(0x10330b, 0x00); HAL_DMD_RIU_WriteByte(0x10330c, 0x01); // reg_ckg_dvbtc_inner1x@0x06[3:0] : MPLLDIV10/4=21.5MHz HAL_DMD_RIU_WriteByte(0x10330d, 0x01); // reg_ckg_dvbtc_inner2x@0x06[11:8]: MPLLDIV10/2=43.2MHz HAL_DMD_RIU_WriteByte(0x10330e, 0x01); // reg_ckg_dvbtc_inner4x@0x07[3:0] : MPLLDIV10=86.4MHz HAL_DMD_RIU_WriteByte(0x10330f, 0x00); HAL_DMD_RIU_WriteByte(0x103310, 0x01); // reg_ckg_dvbtc_outer1x@0x08[3:0] : MPLLDIV10/2=43.2MHz HAL_DMD_RIU_WriteByte(0x103311, 0x01); // reg_ckg_dvbtc_outer2x@0x08[11:8]: MPLLDIV10=86.4MHz HAL_DMD_RIU_WriteByte(0x103312, 0x05); // dvbt_t:0x0000, dvb_c: 0x0004 HAL_DMD_RIU_WriteByte(0x103313, 0x00); HAL_DMD_RIU_WriteByte(0x103314, 0x01); // reg_ckg_dvbtc_adc@0x0a[3:0] : ADC_CLK HAL_DMD_RIU_WriteByte(0x103315, 0x01); // reg_ckg_dvbtc_innc@0x0a[11:8] HAL_DMD_RIU_WriteByte(0x103316, 0x01); // reg_ckg_dvbtc_eq8x@0x0b[3:0] : MPLLDIV3/2=144MHz HAL_DMD_RIU_WriteByte(0x103317, 0x01); // reg_ckg_dvbtc_eq@0x0b[11:8] : MPLLDIV3/16=18MHz HAL_DMD_RIU_WriteByte(0x103318, 0x11); // reg_ckg_dvbtc_sram0~3@0x0c[13:0] HAL_DMD_RIU_WriteByte(0x103319, 0x11); HAL_DMD_RIU_WriteByte(0x103308, 0x01); // parallel mode:0x0001 / serial mode: 0x0401 HAL_DMD_RIU_WriteByte(0x103309, 0x05); // reg_ckg_dvbtc_ts@0x04 HAL_DMD_RIU_WriteByte(0x101E3E, 0x00); // DVBT = BIT1 clear return TRUE; } /*********************************************************************************** Subject: Load DSP code to chip Function: INTERN_DVBC_LoadDSPCode Parmeter: Return: MS_BOOL Remark: ************************************************************************************/ static MS_BOOL INTERN_DVBC_LoadDSPCode(void) { MS_U8 udata = 0x00; MS_U16 i; MS_U16 fail_cnt=0; #if (DBG_DUMP_LOAD_DSP_TIME==1) MS_U32 u32Time; #endif #ifndef INTERN_DVBC_LOAD_FW_FROM_CODE_MEMORY BININFO BinInfo; MS_BOOL bResult; MS_U32 u32GEAddr; MS_U8 Data; MS_S8 op; MS_U32 srcaddr; MS_U32 len; MS_U32 SizeBy4K; MS_U16 u16Counter=0; MS_U8 *pU8Data; #endif #if 0 if(HAL_DMD_RIU_ReadByte(0x101E3E)) { ULOGD("DEMOD","Warring! Reg[0x101E3E]=%d\n", HAL_DMD_RIU_ReadByte(0x101E3E)); return FALSE; } #endif // MDrv_Sys_DisableWatchDog(); // HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x00, 0x01); // reset VD_MCU HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x00, 0x00); // reset VD_MCU HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x01, 0x00); // disable SRAM HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x03, 0x50); // enable "vdmcu51_if" HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x03, 0x51); // enable auto-increase HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x04, 0x00); // sram address low byte HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x05, 0x00); // sram address high byte //// Load code thru VDMCU_IF //// ULOGD("DEMOD",">Load Code.....\n"); #ifdef INTERN_DVBC_LOAD_FW_FROM_CODE_MEMORY for ( i = 0; i < sizeof(INTERN_DVBC_table); i++) { HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x0C, INTERN_DVBC_table[i]); // write data to VD MCU 51 code sram } #else BinInfo.B_ID = BIN_ID_INTERN_DVBC_DEMOD; msAPI_MIU_Get_BinInfo(&BinInfo, &bResult); if ( bResult != PASS ) { return FALSE; } //ULOGD("DEMOD","\t DEMOD_MEM_ADR =%08LX\n", ((DEMOD_MEM_ADR & MIU1) ? (DEMOD_MEM_ADR | MIU_INTERVAL) : (DEMOD_MEM_ADR))); #ifdef SUPPORT_AP_BIN_IN_FLASH_2 InfoBlock_Flash_2_Checking_Start(&BinInfo); #endif #if OBA2 MApi_BDMA_CopyFromResource(BinInfo.B_FAddr, _PA2VA((DEMOD_MEM_MEMORY_TYPE & MIU1) ? (DEMOD_MEM_ADR | MIU_INTERVAL) : (DEMOD_MEM_ADR)), MemAlign(BinInfo.B_Len, 8)); #else msAPI_MIU_Copy(BinInfo.B_FAddr, ((DEMOD_MEM_MEMORY_TYPE & MIU1) ? (DEMOD_MEM_ADR | MIU_INTERVAL) : (DEMOD_MEM_ADR)), MemAlign(BinInfo.B_Len, 8), MIU_FLASH2SDRAM); #endif #ifdef SUPPORT_AP_BIN_IN_FLASH_2 InfoBlock_Flash_2_Checking_End(&BinInfo); #endif //W1BaseAddr = MDrv_Sys_GetXdataWindow1Base(); SizeBy4K=BinInfo.B_Len/0x1000; //ULOGD("DEMOD","\t RRR: SizeBy4K=%d (L=%d)\n", SizeBy4K,BinInfo.B_Len); #if (DBG_DUMP_LOAD_DSP_TIME==1) u32Time = msAPI_Timer_GetTime0(); #endif u32GEAddr = _PA2VA(((DEMOD_MEM_MEMORY_TYPE & MIU1) ? (DEMOD_MEM_ADR | MIU_INTERVAL) : (DEMOD_MEM_ADR))); for (i=0;i<=SizeBy4K;i++) { if(i==SizeBy4K) len=BinInfo.B_Len%0x1000; else len=0x1000; srcaddr = u32GEAddr+(0x1000*i); //ULOGD("DEMOD","\t i = %08X\n", i); //ULOGD("DEMOD","\t len = %08X\n", len); op = 1; u16Counter = 0 ; //ULOGD("DEMOD","\t (B=0x%x)(Src=0x%x)Data =",i,srcaddr); while(len--) { u16Counter ++ ; //ULOGD("DEMOD","file: %s, line: %d\n", __FILE__, __LINE__); //pU8Data = (MS_U8 *)(srcaddr|0x80000000); #if OBA2 pU8Data = (MS_U8 *)(srcaddr); #else pU8Data = (MS_U8 *)(srcaddr|0x80000000); #endif Data = *pU8Data; #if 0 if(u16Counter < 0x100) ULOGD("DEMOD","0x%bx,", Data); #endif HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x0C, Data); // write data to VD MCU 51 code sram srcaddr += op; } // ULOGD("DEMOD","\n\n\n"); } #if (DBG_DUMP_LOAD_DSP_TIME==1) ULOGD("DEMOD","------> INTERN_DVBC Load DSP Time: (%lu)\n", msAPI_Timer_DiffTimeFromNow(u32Time)) ; #endif #endif //// Content verification //// ULOGD("DEMOD",">Verify Code...\n"); HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x04, 0x00); // sram address low byte HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x05, 0x00); // sram address high byte #ifdef INTERN_DVBC_LOAD_FW_FROM_CODE_MEMORY for ( i = 0; i < sizeof(INTERN_DVBC_table); i++) { udata = HAL_DMD_RIU_ReadByte(DMDMcuBase + 0x10); // read sram data if (udata != INTERN_DVBC_table[i]) { ULOGD("DEMOD",">fail add = 0x%x\n", i); ULOGD("DEMOD",">code = 0x%x\n", INTERN_DVBC_table[i]); ULOGD("DEMOD",">data = 0x%x\n", udata); if (fail_cnt > 10) { ULOGD("DEMOD",">DVB-C DSP Loadcode fail!"); return false; } fail_cnt++; } } #else for (i=0;i<=SizeBy4K;i++) { if(i==SizeBy4K) len=BinInfo.B_Len%0x1000; else len=0x1000; srcaddr = u32GEAddr+(0x1000*i); //ULOGD("DEMOD","\t i = %08LX\n", i); //ULOGD("DEMOD","\t len = %08LX\n", len); op = 1; u16Counter = 0 ; //ULOGD("DEMOD","\t (B=0x%bx)(Src=0x%x)Data =",i,srcaddr); while(len--) { u16Counter ++ ; //ULOGD("DEMOD","file: %s, line: %d\n", __FILE__, __LINE__); //pU8Data = (MS_U8 *)(srcaddr|0x80000000); #if OBA2 pU8Data = (MS_U8 *)(srcaddr); #else pU8Data = (MS_U8 *)(srcaddr|0x80000000); #endif Data = *pU8Data; #if 0 if(u16Counter < 0x100) ULOGD("DEMOD","0x%bx,", Data); #endif udata = HAL_DMD_RIU_ReadByte(DMDMcuBase + 0x10); // read sram data if (udata != Data) { ULOGD("DEMOD",">fail add = 0x%lx\n", (MS_U32)((i*0x1000)+(0x1000-len))); ULOGD("DEMOD",">code = 0x%x\n", Data); ULOGD("DEMOD",">data = 0x%x\n", udata); if (fail_cnt++ > 10) { ULOGD("DEMOD",">DVB-C DSP Loadcode fail!"); return false; } } srcaddr += op; } // ULOGD("DEMOD","\n\n\n"); } #endif HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x03, 0x50); // diable auto-increase HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x03, 0x00); // disable "vdmcu51_if" HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x01, 0x01); // enable SRAM HAL_DMD_RIU_WriteByte(DMDMcuBase + 0x00, 0x00); // release VD_MCU ULOGD("DEMOD",">DSP Loadcode done."); //while(load_data_variable); #if 0 INTERN_DVBC_Config(6875, 128, 36125, 0,1); INTERN_DVBC_Active(ENABLE); while(1); #endif HAL_DMD_RIU_WriteByte(0x101E3E, 0x04); // DVBT = BIT1 -> 0x02 return TRUE; } /*********************************************************************************** Subject: DVB-T CLKGEN initialized function Function: INTERN_DVBC_Power_On_Initialization Parmeter: Return: MS_BOOL Remark: ************************************************************************************/ void INTERN_DVBC_InitClkgen(MS_BOOL bRFAGCTristateEnable) { MS_U8 temp_val; //move to drvSYS MS_U8 tmp; //MS_U8 udatatemp = 0x00; /************************************************************************ * T10 U01 * This bit0 is mux for DMD muc and HK, * bit0: 0:HK can rw bank 0x1120, 1: DMD mcu can rw bank 0x1120; ************************************************************************/ HAL_DMD_RIU_WriteByte(0x101E39, 0x00); //mux from DMD MCU to HK. // ================================================================ // Start TOP CLKGEN setting // ================================================================ // Set DMDMCU clock // [4:0] : reg_ckg_dmdmcu // [0] : disable clock // [1] : invert clock // [4:2]: Select clock source // 000: clk_172_buf // 001: clk_160_buf // 010: clk_144_buf // 011: clk_123_buf // 100: clk_108_buf // 101: 1'b0 // 110: 1'b0 // 111: clk_xtal_12M_buf // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h0f, 2'b01, 16'h0010); // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h0f, 2'b01, 16'h0010); HAL_DMD_RIU_WriteByte(0x10331e,0x10); // Set parallel TS clock // [11] : reg_ckg_demod_test_in_en = 0 // 0: select internal ADC CLK // 1: select external test-in clock // [10] : reg_ckg_dvbtm_ts_out_mode = 1 // 0: select gated clock // 1: select free-run clock // [9] : reg_ckg_atsc_dvbtc_ts_inv = 1 // 0: normal phase to pad // 1: invert phase to pad // [8] : reg_ckg_atsc_dvb_div_sel = 1 // 0: select clk_dmplldiv5 // 1: select clk_dmplldiv3 // [4:0]: reg_ckg_dvbtm_ts_divnum = 19 // => TS clock = (864/3)/(2*(19+1)) = 7.2MHz // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h00, 2'b11, 16'h0713); // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h00, 2'b11, 16'h0713); temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x07; HAL_DMD_RIU_WriteByte(0x103301,temp_val); HAL_DMD_RIU_WriteByte(0x103300,0x13); // Enable ATSC, DVBTC TS clock // [3:0] : reg_ckg_atsc_ts // [0] : disable clock // [1] : invert clock // [3:2] : Select clock source // 00: clk_atsc_dvb_div // 01: 62 MHz // 10: 54 MHz // 11: reserved // [11:8]: reg_ckg_dvbtc_ts // [0] : disable clock // [1] : invert clock // [3:2] : Select clock source // 00: clk_atsc_dvb_div // 01: 62 MHz // 10: 54 MHz // 11: reserved // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h04, 2'b11, 16'h0000); // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h04, 2'b11, 16'h0000); HAL_DMD_RIU_WriteByte(0x103309,0x00); HAL_DMD_RIU_WriteByte(0x103308,0x00); // Enable ADC clock in clkgen_demod!!! // ^^^^^^^^^^^^^^^ // [3:0]: reg_ckg_dvbtc_adc // [0] : disable clock // [1] : invert clock // [2] : Select clock source => for demod clkgen clk_dvbtc_adc // 0:clk_dmdadc // 1:clk_vif_ssc_mux // ^^^^^^^^^^^^^^^ // if(reg_vif_ssc_en) => clk_vif_ssc_43p2_p(43.2 MHz) // else => clk_dmplldiv10_div2(43.2 MHz) // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h0a, 2'b11, 16'h0000); // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h0a, 2'b11, 16'h0000); HAL_DMD_RIU_WriteByte(0x103315,0x00); HAL_DMD_RIU_WriteByte(0x103314,0x00); // Enable VIF DAC clock in clkgen_demod!!! // ^^^^^^^^^^^^^^^ // [3:0] : reg_ckg_vifdbb_dac // [11:8]: reg_ckg_vifdbb_vdac // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h0d, 2'b11, 16'h0000); // Reset TS divider // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h01, 2'b01, 16'h0001); // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h01, 2'b01, 16'h0001); HAL_DMD_RIU_WriteByte(0x103302,0x01); // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h01, 2'b01, 16'h0000); // `RIU_W((`RIUBASE_CLKGEN1>>1)+7'h01, 2'b01, 16'h0000); HAL_DMD_RIU_WriteByte(0x103302,0x00); // ================================================================ // Start Demod CLKGEN setting // ================================================================ // Enable clk_atsc_adcd_sync // [3:0]: reg_ckg_atsc_adcd_sync // [0] : disable clock // [1] : invert clock // [3:2]: Select clock source // 00: clk_dmdadc_sync // 01: clk_atsc50_p // ^^^^^^^^^^^^ // if(reg_atsc_adc_sel_mplldiv2) => clk_dmplldiv2_div7(49.7 MHz) // else => clk_dmplldiv17(50.82 MHz) // 10: clk_atsc25_p // ^^^^^^^^^^^^ // if(reg_atsc_adc_sel_mplldiv2) => clk_dmplldiv2_div7_div2(24.85 MHz) // else => clk_dmplldiv17_div2(25.41 MHz) // 11: 1'b0 // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h05, 2'b11, 16'h0000); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h05, 2'b11, 16'h0000); HAL_DMD_RIU_WriteByte(0x111f0b,0x00); HAL_DMD_RIU_WriteByte(0x111f0a,0x00); // @0x3511 // [2:0] : reg_ckg_dvbt_outer1x // [0] : disable clock // [1] : invert clock // [2] : Select clock source // 00: dvb_clk48_buf // 01: dvb_clk43_buf // 10: 1'b0 // 11: DFT_CLK // [6:4] : reg_ckg_dvbt_outer2x // [4] : disable clock // [5] : invert clock // [6] : Select clock source // 00: dvb_clk96_buf // 01: dvb_clk86_buf // 10: 1'b0 // 11: DFT_CLK // [11:8]: reg_ckg_dvbtc_outer2x // [8] : disable clock // [9] : invert clock // [11:10]: Select clock source // 00: mpll_clk57p6_buf // 01: dvb_clk43_buf // 10: dvb_clk86_buf // 11: dvb_clk96_buf // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h11, 2'b11, 16'h0844); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h11, 2'b11, 16'h0844); HAL_DMD_RIU_WriteByte(0x111f23,0x08); HAL_DMD_RIU_WriteByte(0x111f22,0x44); // @0x3516 // [2:0] : reg_ckg_dvbc_inner // [0] : disable clock // [1] : invert clock // [2]: Select clock source // 0: dvb_clk48_buf // 1: 1'b0 // [6:4] : reg_ckg_dvbc_inner // [4] : disable clock // [5] : invert clock // [6]: Select clock source // 0: mpll_clk18_buf // 1: 1'b0 // [10:8] : reg_ckg_dvbc_inner // [8] : disable clock // [9] : invert clock // [10]: Select clock source // 0: mpll_clk144_buf // 1: 1'b0 // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h15, 2'b11, 16'h0000); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h15, 2'b11, 16'h0000); HAL_DMD_RIU_WriteByte(0x111f2b,0x00); HAL_DMD_RIU_WriteByte(0x111f2a,0x00); // @0x351d // [4:0] : reg_ckg_dvbtm_adc_eq_1x // [0] : disable clock // [1] : invert clock // [2] : Select clock source // 00: adc_clk_buf // 01: 1'b0 // 10: 1'b0 // 11: DFT_CLK // [12:8]: reg_ckg_dvbtm_adc_eq_0p5x // [4] : disable clock // [5] : invert clock // [6]: Select clock source // 00: clk_adc_div2_buf // 01: 1'b0 // 10: 1'b0 // 11: DFT_CLK // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h1d, 2'b11, 16'h0000); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h1d, 2'b11, 16'h0000); HAL_DMD_RIU_WriteByte(0x111f3b,0x00); HAL_DMD_RIU_WriteByte(0x111f3a,0x00); // @0x3512 // [11:8]: reg_ckg_acifir // [8] : disable clock // [9] : invert clock // [11:10]: Select clock source // 000: clk_atsc25_p // 001: clk_dmdadc // 010: clk_vif_ssc_mux // 011: 1'b0 // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h12, 2'b11, 16'h0400); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h12, 2'b11, 16'h0400); HAL_DMD_RIU_WriteByte(0x111f25,0x04); HAL_DMD_RIU_WriteByte(0x111f24,0x00); // @0x3571 //Maserati // [4:0] : reg_ckg_dvbtm_sram_t12x_t24x_srd1x // [13:8] : reg_ckg_dvbtm_sram_t14x_t24x_srd1x // [0] : disable clock // [1] : invert clock // [4:2] : Select clock source // 000: dvb_clk96_buf // 001: dvb_clk86_buf // 010: adc_clk_buf // 011: mpll_clk18_buf // 100: clk_dmplldiv10 // 100: clk_adc1x_eq1x_p // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h71, 2'b11, 16'h0810); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h71, 2'b11, 16'h0810); HAL_DMD_RIU_WriteByte(0x111fe3,0x08); HAL_DMD_RIU_WriteByte(0x111fe2,0x10); // [3:0] : reg_ckg_dtmb_eq2x_inner2x_12x // [0] : disable clock // [1] : invert clock // [3:2]: Select clock source // 00: dtmb_clk288_buf(256 MHz) // 01: dtmb_eq_sram_clk36_buf(32 MHz) // 10: dtmb_eq_sram_clk216_buf(192 MHz) // 11: 1'b0 // [7:4] : reg_ckg_dtmb_inner1x_dvbc_eq1x => CCI LMS 1x // ^^^^^^^^^^ // [0] : disable clock // [1] : invert clock // [3:2]: Select clock source // 00: dtmb_clk18_buf(16 MHz) => DTMB // 01: clk_dmplldiv3_div16(18 MHz) => DVBC,ISDBT(>= (24/2=12)) // 10: clk_dmplldiv10_div8(10.8 MHz)=> DVBT // 11: clk_cci_lms_1x_atsc_p_buf => ATSC // ^^^^^^^^^^^^^^^^^^^^^^^^^ // if(reg_atsc_eq_sel_mplldiv2) => clk_dmplldiv2_div2_inv_div8(21.75 MHz) // else => clk_dmplldiv5_inv_div8(21.6 MHz) // [11:8] : reg_ckg_dtmb_inner4x_dvbc_eq4x => CCI LMS 4x // ^^^^^^^^^^ // [0] : disable clock // [1] : invert clock // [3:2]: Select clock source // 00: dtmb_clk72_buf(64 MHz) => DTMB // 01: clk_dmplldiv3_div4(72 MHz) => DVBC,ISDBT(>= 48) // 10: clk_dmplldiv10_div2(43.2 MHz)=> DVBT // 11: clk_cci_lms_4x_atsc_p_buf => ATSC // ^^^^^^^^^^^^^^^^^^^^^^^^^ // if(reg_atsc_eq_sel_mplldiv2) => clk_dmplldiv2_div2_inv_div2(87 MHz) // else => clk_dmplldiv5_inv_div2(86.4 MHz) // [15:12]: reg_ckg_dtmb_sram_dump // [0] : disable clock // [1] : invert clock // [3:2]: Select clock source // 00: dtmb_clk18_buf(16 MHz) // 01: dtmb_sram_dump_clk144_buf(128 MHz) // 10: dtmb_sram_dump_clk216_buf(192 MHz) // 11: dtmb_sram_dump_dmplldiv5_buf(153.6 MHz) // `RIU_W((`RIUBASE_DEMOD_8>>1)+7'h38, 2'b11, 16'h1001); // `RIU_W((`RIUBASE_DEMOD_8>>1)+7'h38, 2'b11, 16'h1001); HAL_DMD_RIU_WriteByte(0x152971,0x10); HAL_DMD_RIU_WriteByte(0x152970,0x01); // @0x353b //Maserati // [15:12] : reg_ckg_dvbtm_sram_t12x_t24x_srd1x_isdbt_inner4x // [12] : disable clock // [13] : invert clock // [15:14] : Select clock source // 00: clk_dvbtm_sram_t12x_t24x_srd1x_p // 01: clk_isdbt_inner4x_p // 10: clk_share_dtmb_eq0p5x_isdbt_sram0_mux // 11: clk_adc1x_eq1x_p // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h3b, 2'b10, 16'h0111); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h3b, 2'b10, 16'h0111); HAL_DMD_RIU_WriteByte(0x111f77,0x01); // @0x353c //Maserati // [ 3: 0] reg_ckg_dvbtm_sram_t14x_t24x_srd1x_vifssc_isdbt_inner4x[3:0] // [ 6: 4] reg_ckg_dvbtm_sram_t12x_t22x_isdbt_inner2x[2:0] // [10: 8] reg_ckg_dvbtm_sram_t11x_t22x_isdbt_inner2x[2:0] // [14:12] reg_ckg_dvbtm_sram_t12x_t24x_isdbt_outer6x // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h3c, 2'b11, 16'h1110); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h3c, 2'b11, 16'h1110); HAL_DMD_RIU_WriteByte(0x111f79,0x11); HAL_DMD_RIU_WriteByte(0x111f78,0x10); // @0x3571 //Maserati // [4:0] : reg_ckg_dvbtm_sram_t12x_t24x_srd1x // [13:8] : reg_ckg_dvbtm_sram_t14x_t24x_srd1x // [0] : disable clock // [1] : invert clock // [4:2] : Select clock source // 000: dvb_clk96_buf // 001: dvb_clk86_buf // 010: adc_clk_buf // 011: mpll_clk18_buf // 100: clk_dmplldiv10 // 100: clk_adc1x_eq1x_p // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h71, 2'b11, 16'h0811); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h71, 2'b11, 16'h0811); HAL_DMD_RIU_WriteByte(0x111fe3,0x08); HAL_DMD_RIU_WriteByte(0x111fe2,0x11); // @0x3578 //Maserati // [4:0] : reg_ckg_dvbt2_inner2x_srd0p5x // [0] : disable clock // [1] : invert clock // [4:2] : Select clock source // 000: dvb_clk48_buf // 001: dvb_clk43_buf // 010: clk_adc_div2_buf // 011: mpll_clk9_buf // 100: clk_adc0p5x_eq0p5x_p // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h78, 2'b01, 16'h0008); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h78, 2'b01, 16'h0008); HAL_DMD_RIU_WriteByte(0x111ff0,0x08); // @Macan // [ 4: 0] reg_ckg_dvbtm_sram_t14x_t24x // [12: 8] reg_ckg_dvbtm_ts_in // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h18, 2'b10, 16'h1c01); // `RIU_W((`RIUBASE_CLKGEN_DMD>>1)+7'h18, 2'b10, 16'h1c01); HAL_DMD_RIU_WriteByte(0x111f31,0x1c); // ================================================================ // Select reg_DMDTOP and reg_DMDANA are controlled by which MCU // ================================================================ // reg_dmdtop_dmd_sel=test_chip_top.chip_top.reg_chip_top.reg_CHIPTOP_inst.reg_chiptop_dummy_0[8]: 0x1c // 1'b0->reg_DMDTOP control by HK_MCU. // wriu 0x101e39 8'bxxxx_xxx0 // 1'b1->reg_DMDTOP control by DMD_MCU. // wriu 0x101e39 8'bxxxx_xxx1 // reg_dmd_ana_regsel=test_chip_top.chip_top.reg_chip_top.reg_CHIPTOP_inst.reg_chiptop_dummy_0[9]: 0x1c // 1'b0->reg_DMDANA control by HK_MCU. // wriu 0x101e39 8'bxxxx_xx0x // 1'b1->reg_DMDANA control by DMD_MCU. // wriu 0x101e39 8'bxxxx_xx1x // `RIU_W((`RIUBASE_CHIP>>1)+7'h1c, 2'b10, 16'h0300); // `RIU_W((`RIUBASE_CHIP>>1)+7'h1c, 2'b10, 16'h0300); HAL_DMD_RIU_WriteByte(0x101E39, 0x03); //mux from DMD MCU to HK. } /*********************************************************************************** Subject: Power on initialized function Function: INTERN_DVBC_Power_On_Initialization Parmeter: Return: MS_BOOL Remark: ************************************************************************************/ MS_BOOL INTERN_DVBC_Power_On_Initialization(MS_BOOL bRFAGCTristateEnable, MS_U8 u8ADCIQMode, MS_U8 u8PadSel, MS_BOOL bPGAEnable, MS_U8 u8PGAGain, const MS_U8 *u8DMD_DVBC_DSPRegInitExt, MS_U8 u8DMD_DVBC_DSPRegInitSize) { MS_U8 status = true; ULOGD("DEMOD","INTERN_DVBC_Power_On_Initialization\n"); #if defined(PWS_ENABLE) Mapi_PWS_Stop_VDMCU(); #endif INTERN_DVBC_InitClkgen(bRFAGCTristateEnable); HAL_DMD_ADC_IQ_Switch(u8ADCIQMode, u8PadSel, bPGAEnable, u8PGAGain); //// Firmware download ////////// ULOGD("DEMOD","INTERN_DVBC Load DSP...\n"); //MsOS_DelayTask(100); //if (HAL_DMD_RIU_ReadByte(0x101E3E) != 0x04) // DVBT = BIT1 -> 0x02 { if (INTERN_DVBC_LoadDSPCode() == FALSE) { ULOGD("DEMOD","DVB-C Load DSP Code Fail\n"); return FALSE; } else { ULOGD("DEMOD","DVB-C Load DSP Code OK\n"); } } status &= INTERN_DVBC_Reset(); status &= INTERN_DVBC_DSPReg_Init(u8DMD_DVBC_DSPRegInitExt, u8DMD_DVBC_DSPRegInitSize); return status; } /************************************************************************************************ Subject: Driving control Function: INTERN_DVBC_Driving_Control Parmeter: bInversionEnable : TRUE For High Return: void Remark: *************************************************************************************************/ void INTERN_DVBC_Driving_Control(MS_BOOL bEnable) { MS_U8 u8Temp; u8Temp = HAL_DMD_RIU_ReadByte(0x101E10); if (bEnable) { u8Temp = u8Temp | 0x01; //bit0: clk, bit1~8:data , bit9: sync, bit10:valid } else { u8Temp = u8Temp & (~0x01); } ULOGD("DEMOD","---> INTERN_DVBC_Driving_Control(Bit0) = 0x%x \n",u8Temp); HAL_DMD_RIU_WriteByte(0x101E10, u8Temp); } /************************************************************************************************ Subject: Clk Inversion control Function: INTERN_DVBC_Clk_Inversion_Control Parmeter: bInversionEnable : TRUE For Inversion Action Return: void Remark: *************************************************************************************************/ void INTERN_DVBC_Clk_Inversion_Control(MS_BOOL bInversionEnable) { MS_U8 u8Temp; u8Temp = HAL_DMD_RIU_ReadByte(0x103301); if (bInversionEnable) { u8Temp = u8Temp | 0x02; //bit 9: clk inv } else { u8Temp = u8Temp & (~0x02); } ULOGD("DEMOD","---> Inversion(Bit9) = 0x%x \n",u8Temp); HAL_DMD_RIU_WriteByte(0x103301, u8Temp); } /************************************************************************************************ Subject: Transport stream serial/parallel control Function: INTERN_DVBC_Serial_Control Parmeter: bEnable : TRUE For serial Return: MS_BOOL : Remark: *************************************************************************************************/ MS_BOOL INTERN_DVBC_Serial_Control(MS_BOOL bEnable, MS_U8 u8TSClk) { MS_U8 status = true; MS_U8 temp_val; ULOGD("DEMOD"," @INTERN_DVBC_ts... u8TSClk=%d\n", u8TSClk); if (u8TSClk == 0xFF) u8TSClk=0x13; if (bEnable) //Serial mode for TS pad { // serial HAL_DMD_RIU_WriteByte(0x103308, 0x01); // serial mode: 0x0401 HAL_DMD_RIU_WriteByte(0x103309, 0x04); // reg_ckg_dvbtc_ts@0x04 HAL_DMD_RIU_WriteByte(0x103300, 0x00); // serial mode 0x0400 #if(INTERN_DVBC_TS_SERIAL_INVERSION == 0) //HAL_DMD_RIU_WriteByte(0x103301, 0x04); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x04; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #else // HAL_DMD_RIU_WriteByte(0x103301, 0x07); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x07; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #endif //move to drvSYS HAL_DMD_RIU_WriteByte(0x101EA5, HAL_DMD_RIU_ReadByte(0x101EA5)&0xEF); // PAD_TS1 is used as output //move to drvSYS HAL_DMD_RIU_WriteByte(0x101EAF, HAL_DMD_RIU_ReadByte(0x101EAF)&0xE3); // PAD_TS1 Disable TS CLK PAD //// INTERN_DVBC TS Control: Serial ////////// status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_TS_SERIAL, TS_SERIAL); #if(INTERN_DVBC_TS_SERIAL_INVERSION == 0) status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_TS_CLK_INV, 0); #else status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_TS_CLK_INV, 1); #endif gsCmdPacketDVBC.cmd_code = CMD_TS_CTRL; gsCmdPacketDVBC.param[0] = TS_SERIAL; #if(INTERN_DVBC_TS_SERIAL_INVERSION == 0) gsCmdPacketDVBC.param[1] = 0;//TS_CLK_NO_INV; #else gsCmdPacketDVBC.param[1] = 1;//TS_CLK_INVERSE; #endif status &= INTERN_DVBC_Cmd_Packet_Send(&gsCmdPacketDVBC, 2); } else { //parallel HAL_DMD_RIU_WriteByte(0x103308, 0x01); // parallel mode:0x0001 HAL_DMD_RIU_WriteByte(0x103309, 0x00); // reg_ckg_dvbtc_ts@0x04 //HAL_DMD_RIU_WriteByte(0x103300, 0x11); // parallel mode: 0x0511 => ts_clk=288/(2*(0x11+1))=8MHz HAL_DMD_RIU_WriteByte(0x103300, u8TSClk); // parallel mode: 0x0513 => ts_clk=288/(2*(0x16+1))=6.26MHz //@@++-- #if(INTERN_DVBC_TS_PARALLEL_INVERSION == 0) //HAL_DMD_RIU_WriteByte(0x103301, 0x05); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x05; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #else //HAL_DMD_RIU_WriteByte(0x103301, 0x07); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x07; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #endif //move to drvSYS HAL_DMD_RIU_WriteByte(0x101EA5, HAL_DMD_RIU_ReadByte(0x101EA5)|0x10); // PAD_TS1 is used as output //move to drvSYS HAL_DMD_RIU_WriteByte(0x101EAF, (HAL_DMD_RIU_ReadByte(0x101EAF)&0xC0)|0x11); // PAD_TS1 enable TS clk pad //// INTERN_DVBC TS Control: Parallel ////////// status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_TS_SERIAL, TS_PARALLEL); #if(INTERN_DVBC_TS_SERIAL_INVERSION == 0) status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_TS_CLK_INV, 0); #else status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_TS_CLK_INV, 1); #endif //// INTERN_DVBC TS Control: Parallel ////////// gsCmdPacketDVBC.cmd_code = CMD_TS_CTRL; gsCmdPacketDVBC.param[0] = TS_PARALLEL; #if(INTERN_DVBC_TS_PARALLEL_INVERSION == 0) gsCmdPacketDVBC.param[1] = 0;//TS_CLK_NO_INV; #else gsCmdPacketDVBC.param[1] = 1;//TS_CLK_INVERSE; #endif status &= INTERN_DVBC_Cmd_Packet_Send(&gsCmdPacketDVBC, 2); } #if(INTERN_DVBC_TS_SERIAL_INVERSION == 0) ULOGD("DEMOD","---> Inversion(Bit5) = %d \n",0 ); #else ULOGD("DEMOD","---> Inversion(Bit5) = %d \n",1 ); #endif INTERN_DVBC_Driving_Control(INTERN_DVBC_DTV_DRIVING_LEVEL); return status; } /************************************************************************************************ Subject: TS1 output control Function: INTERN_DVBC_PAD_TS1_Enable Parmeter: flag : TRUE For Turn on TS1, FALSE For Turn off TS1 Return: void Remark: *************************************************************************************************/ void INTERN_DVBC_PAD_TS1_Enable(MS_BOOL flag) { ULOGD("DEMOD"," @INTERN_DVBC_TS1_Enable... \n"); if(flag) // PAD_TS1 Enable TS CLK PAD { //ULOGD("DEMOD","=== TS1_Enable ===\n"); //HAL_DMD_RIU_WriteByte(0x101EA5, HAL_DMD_RIU_ReadByte(0x101EA5)|0x10); //For T3 //HAL_DMD_RIU_WriteByte(0x101EAF, HAL_DMD_RIU_ReadByte(0x101EAF)|0x18); //For T4 //move to drvSYS HAL_DMD_RIU_WriteByte(0x101EAF, HAL_DMD_RIU_ReadByte(0x101EAF)|0x11); //For T8 } else // PAD_TS1 Disable TS CLK PAD { //ULOGD("DEMOD","=== TS1_Disable ===\n"); //HAL_DMD_RIU_WriteByte(0x101EA5, HAL_DMD_RIU_ReadByte(0x101EA5)&0xEF); //For T3 //HAL_DMD_RIU_WriteByte(0x101EAF, HAL_DMD_RIU_ReadByte(0x101EAF)&0xE3); //For T4 //move to drvSYS HAL_DMD_RIU_WriteByte(0x101EAF, HAL_DMD_RIU_ReadByte(0x101EAF)&0xC0); //For T8 } } /************************************************************************************************ Subject: channel change config Function: INTERN_DVBC_Config Parmeter: BW: bandwidth Return: MS_BOOL : Remark: *************************************************************************************************/ MS_BOOL INTERN_DVBC_Config(MS_U16 u16SymbolRate, DMD_DVBC_MODULATION_TYPE eQamMode, MS_U32 u32IFFreq, MS_BOOL bSpecInv, MS_BOOL bSerialTS, MS_U8 u8TSClk, MS_U16 *pu16_symbol_rate_list,MS_U8 u8_symbol_rate_list_num) { MS_U8 status = true; MS_U8 reg_symrate_l, reg_symrate_h; //MS_U16 u16Fc = 0; MS_U8 temp_val; // force // u16SymbolRate = 0; // eQamMode = DMD_DVBC_QAMAUTO; //pu16_symbol_rate_list = pu16_symbol_rate_list; //u8_symbol_rate_list_num = u8_symbol_rate_list_num; //ULOGD("DEMOD"," @INTERN_DVBC_config, SR=%d, QAM=%d, u32IFFreq=%ld, bSpecInv=%d, bSerialTS=%d, u8TSClk=%d\n",u16SymbolRate,eQamMode,u32IFFreq,bSpecInv,bSerialTS, u8TSClk); //ULOGD("DEMOD","INTERN_DVBC_Config, t = %ld\n",MsOS_GetSystemTime()); if (u8TSClk == 0xFF) u8TSClk=0x13; /* switch(u32IFFreq) { case 36125: case 36167: case 36000: case 6000: case 4560: //u16Fc = DVBC_FS - u32IFFreq; DBG_INTERN_DVBC(ULOGD("DEMOD","Fc freq = %ld\n", DVBC_FS - u32IFFreq)); break; case 44000: default: ULOGD("DEMOD","IF frequency not supported\n"); status = false; break; } */ reg_symrate_l = (MS_U8) (u16SymbolRate & 0xff); reg_symrate_h = (MS_U8) (u16SymbolRate >> 8); status &= INTERN_DVBC_Reset(); if (eQamMode == DMD_DVBC_QAMAUTO) { ULOGD("DEMOD","DMD_DVBC_QAMAUTO\n"); status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_OP_AUTO_SCAN_QAM, 0x01); // give default value. status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_QAM, QAM); } else { ULOGD("DEMOD","DMD_DVBC_QAM %d\n", eQamMode); status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_OP_AUTO_SCAN_QAM, 0x00); status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_QAM, eQamMode); } // auto symbol rate enable/disable if (u16SymbolRate == 0) { status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_OP_AUTO_SCAN_SYM_RATE, 0x01); } else { //status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_OP_AUTO_SCAN_SYM_RATE, 0x00); //status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_L, reg_symrate_l); //status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_H, reg_symrate_h); MS_U8 indx = 0; MS_U8 max_len = (E_DMD_DVBC_CFG_BW11_H - E_DMD_DVBC_CFG_BW0_L + 1)/2; status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_OP_AUTO_SCAN_SYM_RATE, 0x00); if (max_len < u8_symbol_rate_list_num) { ULOGD("DEMOD","[a1_dvbc]Error!!! %s, %s, %d, max_len < u8_symbol_rate_list_num\n",__FILE__,__FUNCTION__,__LINE__); // Force dvbc unlock. MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_L, 0x01); MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_H, 0x00); MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW1_L, 0x00); MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW1_H, 0x00); } else if (u8_symbol_rate_list_num == 0) { MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_L, reg_symrate_l); MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_H, reg_symrate_h); } else { for (indx = 0; indx < max_len ; indx++) { if (indx < u8_symbol_rate_list_num) { MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_L + indx*2, (MS_U8)pu16_symbol_rate_list[indx]); MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_L + indx*2 + 1, (MS_U8)(pu16_symbol_rate_list[indx]>>8)); } else { MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_L + indx*2, 0x00); MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_BW0_L + indx*2 + 1, 0x00); } } } } // TS mode status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_TS_SERIAL, bSerialTS? 0x01:0x00); // IQ Swap status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_IQ_SWAP, bSpecInv? 0x01:0x00); // Fc status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_FC_L, (abs(DVBC_FS-u32IFFreq))&0xff); status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_FC_H, (abs((DVBC_FS-u32IFFreq))>>8)&0xff); // Lif status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_OP_LIF_EN, (u32IFFreq < 10000) ? 1 : 0); // Fif status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_FIF_L, (u32IFFreq)&0xff); status &= MDrv_SYS_DMD_VD_MBX_WriteDSPReg(E_DMD_DVBC_CFG_FIF_H, (u32IFFreq>>8)&0xff); //// INTERN_DVBC system init: DVB-C ////////// // gsCmdPacketDVBC.cmd_code = CMD_SYSTEM_INIT; // gsCmdPacketDVBC.param[0] = E_SYS_DVBC; // status &= INTERN_DVBC_Cmd_Packet_Send(&gsCmdPacketDVBC, 1); if (bSerialTS) { // serial HAL_DMD_RIU_WriteByte(0x103308, 0x01); // parallel mode:0x0001 / serial mode: 0x0401 HAL_DMD_RIU_WriteByte(0x103309, 0x04); // reg_ckg_dvbtc_ts@0x04 HAL_DMD_RIU_WriteByte(0x103300, 0x00); // parallel mode: 0x0511 /serial mode 0x0400 #if(INTERN_DVBC_TS_SERIAL_INVERSION == 0) // HAL_DMD_RIU_WriteByte(0x103301, 0x04); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x04; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #else //HAL_DMD_RIU_WriteByte(0x103301, 0x07); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x07; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #endif } else { //parallel HAL_DMD_RIU_WriteByte(0x103308, 0x01); // parallel mode:0x0001 / serial mode: 0x0401 HAL_DMD_RIU_WriteByte(0x103309, 0x00); // reg_ckg_dvbtc_ts@0x04 //HAL_DMD_RIU_WriteByte(0x103300, 0x11); // parallel mode: 0x0511 => ts_clk=288/(2*(0x11+1))=8MHz HAL_DMD_RIU_WriteByte(0x103300, u8TSClk); // parallel mode: 0x0513 => ts_clk=288/(2*(0x16+1))=6.26MHz //@@++-- #if(INTERN_DVBC_TS_PARALLEL_INVERSION == 0) //HAL_DMD_RIU_WriteByte(0x103301, 0x05); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x05; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #else //HAL_DMD_RIU_WriteByte(0x103301, 0x07); // reg_ckg_dvbtmk_ts_out_mode@0x00 temp_val=HAL_DMD_RIU_ReadByte(0x103301); temp_val|=0x07; HAL_DMD_RIU_WriteByte(0x103301,temp_val); #endif } #if (INTERN_DVBC_INTERNAL_DEBUG == 1) INTERN_DVBC_Show_Demod_Version(); #endif return status; } /************************************************************************************************ Subject: enable hw to lock channel Function: INTERN_DVBC_Active Parmeter: bEnable Return: MS_BOOL Remark: *************************************************************************************************/ MS_BOOL INTERN_DVBC_Active(MS_BOOL bEnable) { MS_U8 status = true; MS_U8 reg_frz = 0, reg_frza = 0; ULOGD("DEMOD"," @INTERN_DVBC_active\n"); //// INTERN_DVBC Finite State Machine on/off ////////// #if 0 gsCmdPacketDVBC.cmd_code = CMD_FSM_CTRL; gsCmdPacketDVBC.param[0] = (MS_U8)bEnable; status &= INTERN_DVBC_Cmd_Packet_Send(&gsCmdPacketDVBC, 1); #else HAL_DMD_RIU_WriteByte(0x112600 + (0x0e)*2, 0x01); // FSM_EN #endif #if (1)//vesion check here MDrv_SYS_DMD_VD_MBX_ReadDSPReg(E_DMD_DVBC_PARAM_VERSION, ®_frz); ULOGD("DEMOD","##########DVBC------>(Driver) = 0x%x #########\n" , reg_frz); MDrv_SYS_DMD_VD_MBX_ReadDSPReg(E_DMD_DVBC_OP_RFAGC_EN, ®_frza); ULOGD("DEMOD","##########DVBC------>(FW) = 0x%x #########\n" , reg_frza); if (reg_frz < reg_frza) { while(1) ULOGD("DEMOD","##########--------->Abnormal case, please update demod utopia driver version!!! #########\n"); } else{ ULOGD("DEMOD","##########--------->Normal case! #########\n"); } #endif bDMD_DVBC_NoChannelDetectedWithRFPower = FALSE; u32DMD_DVBC_NoChannelTimeAccWithRFPower = 0; return status; } MS_BOOL INTERN_DVBC_GetLock(DMD_DVBC_GETLOCK_TYPE eType, float fCurrRFPowerDbm, float fNoChannelRFPowerDbm, MS_U32 u32TimeInterval) { MS_U16 u16Address = 0; MS_U8 cData = 0; MS_U8 cBitMask = 0; if (fCurrRFPowerDbm < 100.0f) { if (eType == DMD_DVBC_GETLOCK_NO_CHANNEL) { MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE + 0xE6, &cData); if (cData > 5) { bDMD_DVBC_NoChannelDetectedWithRFPower = FALSE; u32DMD_DVBC_NoChannelTimeAccWithRFPower = 0; } else { if ((fCurrRFPowerDbm1500) { bDMD_DVBC_NoChannelDetectedWithRFPower=1; #ifdef MS_DEBUG ULOGD("DEMOD","INTERN_DVBC_GetLock:DMD_DVBC_GETLOCK_NO_CHANNEL Detected Detected Detected!!\n"); #endif return TRUE; } } #ifdef MS_DEBUG ULOGD("DEMOD","INTERN_DVBC_GetLock:DMD_DVBC_GETLOCK_NO_CHANNEL FSM:%d InputPower:%f Threshold:%f Interval:%ld TimeAcc:%ld NoChannelDetection:%d\n",cData, fCurrRFPowerDbm, fNoChannelRFPowerDbm, u32TimeInterval, u32DMD_DVBC_NoChannelTimeAccWithRFPower, bDMD_DVBC_NoChannelDetectedWithRFPower); #endif } } { switch( eType ) { case DMD_DVBC_GETLOCK_FEC_LOCK: MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE + 0xE6, &cData); #if (INTERN_DVBC_INTERNAL_DEBUG) INTERN_DVBC_info(); #endif ULOGD("DEMOD"," @INTERN_DVBC_GetLock FSM 0x%x\n",cData); if (cData == 0x0C) { if(g_dvbc_lock == 0) { g_dvbc_lock = 1; ULOGD("DEMOD","[T12][DVBC]lock++++\n"); } return TRUE; } else { if(g_dvbc_lock == 1) { g_dvbc_lock = 0; ULOGD("DEMOD","[T12][DVBC]unlock----\n"); } return FALSE; } break; case DMD_DVBC_GETLOCK_PSYNC_LOCK: u16Address = FEC_REG_BASE + 0x2C; //FEC: P-sync Lock, cBitMask = BIT(1); break; case DMD_DVBC_GETLOCK_DCR_LOCK: u16Address = TDP_REG_BASE + 0x45; //DCR Lock, cBitMask = BIT(0); break; case DMD_DVBC_GETLOCK_AGC_LOCK: u16Address = TDP_REG_BASE + 0x29; //AGC Lock, cBitMask = BIT(0); break; case DMD_DVBC_GETLOCK_NO_CHANNEL: u16Address = TOP_REG_BASE + 0xC3; //no channel, cBitMask = BIT(2)|BIT(3)|BIT(4); #ifdef MS_DEBUG { MS_U8 reg_frz=0, FSM=0; MS_U16 u16Timer=0; MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE + 0xE6, &FSM); MDrv_SYS_DMD_VD_MBX_WriteReg(TDF_REG_BASE + 0x16, 0x03); MDrv_SYS_DMD_VD_MBX_ReadReg(TDF_REG_BASE + 0x03, ®_frz); MDrv_SYS_DMD_VD_MBX_WriteReg(TDF_REG_BASE + 0x03, reg_frz | 0x80); MDrv_SYS_DMD_VD_MBX_ReadReg(TDF_REG_BASE + 0x19, &cData); MDrv_SYS_DMD_VD_MBX_WriteReg(TDF_REG_BASE + 0x03, reg_frz); MDrv_SYS_DMD_VD_MBX_ReadReg(0x20DF, ®_frz); u16Timer=(u16Timer<<8)+reg_frz; MDrv_SYS_DMD_VD_MBX_ReadReg(0x20DE, ®_frz); u16Timer=(u16Timer<<8)+reg_frz; ULOGD("DEMOD","DMD_DVBC_GETLOCK_NO_CHANNEL %d %d %x\n",FSM,u16Timer,cData); } #endif break; case DMD_DVBC_GETLOCK_ATV_DETECT: u16Address = TOP_REG_BASE + 0xC4; //ATV detection, cBitMask = BIT(1); // check atv break; case DMD_DVBC_GETLOCK_TR_LOCK: #if 0 // 20111108 temporarily solution u16Address = INNC_REG_BASE + 0x0A*2 + 1; //TR lock indicator, cBitMask = BIT(4); break; #endif case DMD_DVBC_GETLOCK_TR_EVER_LOCK: u16Address = TOP_REG_BASE + 0xC4; //TR lock indicator, cBitMask = BIT(4); break; default: return FALSE; } if (MDrv_SYS_DMD_VD_MBX_ReadReg(u16Address, &cData) == FALSE) return FALSE; if ((cData & cBitMask) != 0) { return TRUE; } return FALSE; } return FALSE; } /**************************************************************************** Subject: To get the Post viterbi BER Function: INTERN_DVBC_GetPostViterbiBer Parmeter: Quility Return: E_RESULT_SUCCESS E_RESULT_FAILURE =>Read I2C fail, INTERN_DVBC_VIT_STATUS_NG Remark: For the Performance issue, here we just return the Post Value.(Not BER) We will not read the Period, and have the "/256/8" *****************************************************************************/ MS_BOOL INTERN_DVBC_GetPostViterbiBer(float *ber) { MS_BOOL status = true; MS_U8 reg = 0, reg_frz = 0; MS_U16 BitErrPeriod; MS_U32 BitErr; MS_U16 PktErr; /////////// Post-Viterbi BER ///////////// // bank 3f 0x03 [1:0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x32, ®_frz); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(FEC_REG_BASE+0x32, reg_frz|0x80); // bank 3f 0x46 [7:0] reg_bit_err_sblprd_7_0 // 0x47 [15:8] reg_bit_err_sblprd_15_8 status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x31, ®); BitErrPeriod = reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x30, ®); BitErrPeriod = (BitErrPeriod << 8)|reg; // bank 3f 0x6a [7:0] reg_bit_err_num_7_0 // 0x6b [15:8] reg_bit_err_num_15_8 // bank 3f 0x6c [7:0] reg_bit_err_num_23_16 // 0x6d [15:8] reg_bit_err_num_31_24 status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x3D, ®); BitErr = reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x3C, ®); BitErr = (BitErr << 8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x3B, ®); BitErr = (BitErr << 8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x3A, ®); BitErr = (BitErr << 8)|reg; INTERN_DVBC_GetPacketErr(&PktErr); // bank 3f 0x03 [1:0] reg_bit_err_num_freeze reg_frz=reg_frz&(~0x80); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(FEC_REG_BASE+0x32, reg_frz); if (BitErrPeriod == 0 ) //protect 0 BitErrPeriod = 1; if (BitErr <=0 ) *ber = 0.5f / ((float)BitErrPeriod*128*188*8); else *ber = (float)BitErr / ((float)BitErrPeriod*128*188*8); ULOGD("DEMOD","INTERN_DVBC PostVitBER = %8.3e \n ", *ber); return status; } /**************************************************************************** Subject: To get the Packet error Function: INTERN_DVBC_GetPacketErr Parmeter: pktErr Return: E_RESULT_SUCCESS E_RESULT_FAILURE =>Read I2C fail, INTERN_DVBT_VIT_STATUS_NG Remark: For the Performance issue, here we just return the Post Value.(Not BER) We will not read the Period, and have the "/256/8" *****************************************************************************/ MS_BOOL INTERN_DVBC_GetPacketErr(MS_U16 *pktErr) { MS_BOOL status = true; MS_U8 reg = 0, reg_frz = 0; MS_U16 PktErr; // bank 3f 0x03 [1:0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x32, ®_frz); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(FEC_REG_BASE+0x32, reg_frz|0x80); // bank 3f 0x66 [7:0] reg_uncrt_pkt_num_7_0 // 0x67 [15:8] reg_uncrt_pkt_num_15_8 status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x3f, ®); PktErr = reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FEC_REG_BASE+0x3e, ®); PktErr = (PktErr << 8)|reg; // bank 3f 0x03 [1:0] reg_bit_err_num_freeze reg_frz=reg_frz&(~0x80); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(FEC_REG_BASE+0x32, reg_frz); ULOGD("DEMOD","INTERN_DVBC PktErr = %d \n ", (int)PktErr); *pktErr = PktErr; return status; } /**************************************************************************** Subject: Read the signal to noise ratio (SNR) Function: INTERN_DVBC_GetSNR Parmeter: None Return: -1 mean I2C fail, otherwise I2C success then return SNR value Remark: *****************************************************************************/ MS_BOOL INTERN_DVBC_GetSNR(float *f_snr) { MS_BOOL status = true; MS_U8 u8Data = 0; // MS_U8 freeze = 0; MS_U16 noisepower = 0; if (TRUE == INTERN_DVBC_GetLock(DMD_DVBC_GETLOCK_PSYNC_LOCK, 200.0f, -200.0f, 0) ) { #if 1 // bank 2c 0x3d [0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE + 0x3a, 0x20); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(INNC_REG_BASE + 0x05, 0x80); // read vk status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x45, &u8Data); noisepower = u8Data; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x44, &u8Data); noisepower = (noisepower<<8)|u8Data; // bank 2c 0x3d [0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE + 0x3a, 0x00); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(INNC_REG_BASE + 0x05, 0x00); #else // bank 2c 0x3d [0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE+0x3d, ®_frz); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE+0x3d, reg_frz|0x01); // read vk status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE2_REG_BASE + 0x6f, &u8Data); noisepower = u8Data; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE2_REG_BASE + 0x6e, &u8Data); noisepower = (noisepower<<8)|u8Data; // bank 2c 0x3d [0] reg_bit_err_num_freeze reg_frz=reg_frz&(~0x01); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE+0x3d, reg_frz); #endif if(noisepower == 0x0000) noisepower = 0x0001; #ifdef MSOS_TYPE_LINUX *f_snr = 10.0f*log10f(65536.0f/(float)noisepower); #else *f_snr = 10.0f*Log10Approx(65536.0f/(float)noisepower); #endif } else { *f_snr = 0.0f; } return status; } MS_BOOL INTERN_DVBC_GetSignalStrength(MS_U16 *strength, const DMD_DVBC_InitData *sDMD_DVBC_InitData, MS_U8 u8SarValue, float fRFPowerDbm) { MS_BOOL status = true; float ch_power_db=0.0f, ch_power_db_rel=0.0f; DMD_DVBC_MODULATION_TYPE Qam_mode; //ULOGD("DEMOD","INTERN_DVBC_GetSignalStrength, t=%ld, RF level=%f, Table=%lx\n",MsOS_GetSystemTime(), fRFPowerDbm, (MS_U32)(sDMD_DVBC_InitData->pTuner_RfagcSsi)); // if (INTERN_DVBC_Lock(COFDM_TPS_LOCK)) //if (INTERN_DVBC_Lock(COFDM_AGC_LOCK)) /* Actually, it's more reasonable, that signal level depended on cable input power level * thougth the signal isn't dvb-t signal. */ // use pointer of IFAGC table to identify // case 1: RFAGC from SAR, IFAGC controlled by demod // case 2: RFAGC from tuner, ,IFAGC controlled by demod status=HAL_DMD_GetRFLevel(&ch_power_db, fRFPowerDbm, u8SarValue, sDMD_DVBC_InitData->pTuner_RfagcSsi, sDMD_DVBC_InitData->u16Tuner_RfagcSsi_Size, sDMD_DVBC_InitData->pTuner_IfagcSsi_HiRef, sDMD_DVBC_InitData->u16Tuner_IfagcSsi_HiRef_Size, sDMD_DVBC_InitData->pTuner_IfagcSsi_LoRef, sDMD_DVBC_InitData->u16Tuner_IfagcSsi_LoRef_Size, sDMD_DVBC_InitData->pTuner_IfagcErr_HiRef, sDMD_DVBC_InitData->u16Tuner_IfagcErr_HiRef_Size, sDMD_DVBC_InitData->pTuner_IfagcErr_LoRef, sDMD_DVBC_InitData->u16Tuner_IfagcErr_LoRef_Size); status &= INTERN_DVBC_GetCurrentModulationType(&Qam_mode); if( (MS_U8)Qam_mode <= (MS_U8)DMD_DVBC_QAM256) { ch_power_db_rel = ch_power_db + intern_dvb_c_qam_ref[(MS_U8)Qam_mode]; } else { ch_power_db_rel = -100.0f; } if(ch_power_db_rel <= -85.0f) {*strength = 0;} else if (ch_power_db_rel <= -80.0f) {*strength = (MS_U16)(0.0f + (ch_power_db_rel+85.0f)*10.0f/5.0f);} else if (ch_power_db_rel <= -75.0f) {*strength = (MS_U16)(10.0f + (ch_power_db_rel+80.0f)*20.0f/5.0f);} else if (ch_power_db_rel <= -70.0f) {*strength = (MS_U16)(30.0f + (ch_power_db_rel+75.0f)*30.0f/5.0f);} else if (ch_power_db_rel <= -65.0f) {*strength = (MS_U16)(60.0f + (ch_power_db_rel+70.0f)*10.0f/5.0f);} else if (ch_power_db_rel <= -55.0f) {*strength = (MS_U16)(70.0f + (ch_power_db_rel+65.0f)*20.0f/10.0f);} else if (ch_power_db_rel <= -45.0f) {*strength = (MS_U16)(90.0f + (ch_power_db_rel+55.0f)*10.0f/10.0f);} else {*strength = 100;} ULOGD("DEMOD",">>> SSI_CH_PWR(dB) = %f , Score = %d<<<\n", ch_power_db, *strength); ULOGD("DEMOD",">>> SSI = %d <<<\n", (int)*strength); return status; } /**************************************************************************** Subject: To get the DVT Signal quility Function: INTERN_DVBC_GetSignalQuality Parmeter: Quility Return: E_RESULT_SUCCESS E_RESULT_FAILURE Remark: Here we have 4 level range <1>.First Range => Quility =100 (You can define it by INTERN_DVBT_SIGNAL_BASE_100) <2>.2th Range => 60 < Quality < 100 (You can define it by INTERN_DVBT_SIGNAL_BASE_60) <3>.3th Range => 10 < Quality < 60 (You can define it by INTERN_DVBT_SIGNAL_BASE_10) <4>.4th Range => Quality <10 *****************************************************************************/ MS_BOOL INTERN_DVBC_GetSignalQuality(MS_U16 *quality, const DMD_DVBC_InitData *sDMD_DVBC_InitData, MS_U8 u8SarValue, float fRFPowerDbm) { float fber; float log_ber; MS_BOOL status = true; DMD_DVBC_MODULATION_TYPE Qam_mode; float f_snr; fRFPowerDbm = fRFPowerDbm; status &= INTERN_DVBC_GetSNR(&f_snr); if (TRUE == INTERN_DVBC_GetLock(DMD_DVBC_GETLOCK_PSYNC_LOCK, 200.0f, -200.0f, 0)) { if (INTERN_DVBC_GetPostViterbiBer(&fber) == FALSE) { ULOGD("DEMOD","\nGetPostViterbiBer Fail!"); return FALSE; } // log_ber = log10(fber) log_ber = (-1.0f)*Log10Approx(1.0f/fber); // Log10Approx() provide 1~2^32 input range only ULOGD("DEMOD","\nLog(BER) = %f",log_ber); status &= INTERN_DVBC_GetCurrentModulationType(&Qam_mode); if (Qam_mode == DMD_DVBC_QAM16) { if(log_ber <= (-5.5f)) *quality = 100; else if(log_ber <= (-5.1f)) *quality = (MS_U16)(90.0f + ((-5.1f)-log_ber)*10.0f/((-5.1f)-(-5.5f))); else if(log_ber <= (-4.9f)) *quality = (MS_U16)(80.0f + ((-4.9f)-log_ber)*10.0f/((-4.9f)-(-5.1f))); else if(log_ber <= (-4.5f)) *quality = (MS_U16)(70.0f + ((-4.5f)-log_ber)*10.0f/((-4.5f)-(-4.9f))); else if(log_ber <= (-3.7f)) *quality = (MS_U16)(60.0f + ((-3.7f)-log_ber)*10.0f/((-3.7f)-(-4.5f))); else if(log_ber <= (-3.2f)) *quality = (MS_U16)(50.0f + ((-3.2f)-log_ber)*10.0f/((-3.2f)-(-3.7f))); else if(log_ber <= (-2.9f)) *quality = (MS_U16)(40.0f + ((-2.9f)-log_ber)*10.0f/((-2.9f)-(-3.2f))); else if(log_ber <= (-2.5f)) *quality = (MS_U16)(30.0f + ((-2.5f)-log_ber)*10.0f/((-2.5f)-(-2.9f))); else if(log_ber <= (-2.2f)) *quality = (MS_U16)(20.0f + ((-2.2f)-log_ber)*10.0f/((-2.2f)-(-2.5f))); else if(log_ber <= (-2.0f)) *quality = (MS_U16)(0.0f + ((-2.0f)-log_ber)*10.0f/((-2.0f)-(-2.2f))); else *quality = 0; } else if (Qam_mode == DMD_DVBC_QAM32) { if(log_ber <= (-5.0f)) *quality = 100; else if(log_ber <= (-4.7f)) *quality = (MS_U16)(90.0f + ((-4.7f)-log_ber)*10.0f/((-4.7f)-(-5.0f))); else if(log_ber <= (-4.5f)) *quality = (MS_U16)(80.0f + ((-4.5f)-log_ber)*10.0f/((-4.5f)-(-4.7f))); else if(log_ber <= (-3.8f)) *quality = (MS_U16)(70.0f + ((-3.8f)-log_ber)*10.0f/((-3.8f)-(-4.5f))); else if(log_ber <= (-3.5f)) *quality = (MS_U16)(60.0f + ((-3.5f)-log_ber)*10.0f/((-3.5f)-(-3.8f))); else if(log_ber <= (-3.0f)) *quality = (MS_U16)(50.0f + ((-3.0f)-log_ber)*10.0f/((-3.0f)-(-3.5f))); else if(log_ber <= (-2.7f)) *quality = (MS_U16)(40.0f + ((-2.7f)-log_ber)*10.0f/((-2.7f)-(-3.0f))); else if(log_ber <= (-2.4f)) *quality = (MS_U16)(30.0f + ((-2.4f)-log_ber)*10.0f/((-2.4f)-(-2.7f))); else if(log_ber <= (-2.2f)) *quality = (MS_U16)(20.0f + ((-2.2f)-log_ber)*10.0f/((-2.2f)-(-2.4f))); else if(log_ber <= (-2.0f)) *quality = (MS_U16)(0.0f + ((-2.0f)-log_ber)*10.0f/((-2.0f)-(-2.2f))); else *quality = 0; } else if (Qam_mode == DMD_DVBC_QAM64) { if(log_ber <= (-5.4f)) *quality = 100; else if(log_ber <= (-5.1f)) *quality = (MS_U16)(90.0f + ((-5.1f)-log_ber)*10.0f/((-5.1f)-(-5.4f))); else if(log_ber <= (-4.9f)) *quality = (MS_U16)(80.0f + ((-4.9f)-log_ber)*10.0f/((-4.9f)-(-5.1f))); else if(log_ber <= (-4.3f)) *quality = (MS_U16)(70.0f + ((-4.3f)-log_ber)*10.0f/((-4.3f)-(-4.9f))); else if(log_ber <= (-3.7f)) *quality = (MS_U16)(60.0f + ((-3.7f)-log_ber)*10.0f/((-3.7f)-(-4.3f))); else if(log_ber <= (-3.2f)) *quality = (MS_U16)(50.0f + ((-3.2f)-log_ber)*10.0f/((-3.2f)-(-3.7f))); else if(log_ber <= (-2.9f)) *quality = (MS_U16)(40.0f + ((-2.9f)-log_ber)*10.0f/((-2.9f)-(-3.2f))); else if(log_ber <= (-2.4f)) *quality = (MS_U16)(30.0f + ((-2.4f)-log_ber)*10.0f/((-2.4f)-(-2.9f))); else if(log_ber <= (-2.2f)) *quality = (MS_U16)(20.0f + ((-2.2f)-log_ber)*10.0f/((-2.2f)-(-2.4f))); else if(log_ber <= (-2.05f)) *quality = (MS_U16)(0.0f + ((-2.05f)-log_ber)*10.0f/((-2.05f)-(-2.2f))); else *quality = 0; } else if (Qam_mode == DMD_DVBC_QAM128) { if(log_ber <= (-5.1f)) *quality = 100; else if(log_ber <= (-4.9f)) *quality = (MS_U16)(90.0f + ((-4.9f)-log_ber)*10.0f/((-4.9f)-(-5.1f))); else if(log_ber <= (-4.7f)) *quality = (MS_U16)(80.0f + ((-4.7f)-log_ber)*10.0f/((-4.7f)-(-4.9f))); else if(log_ber <= (-4.1f)) *quality = (MS_U16)(70.0f + ((-4.1f)-log_ber)*10.0f/((-4.1f)-(-4.7f))); else if(log_ber <= (-3.5f)) *quality = (MS_U16)(60.0f + ((-3.5f)-log_ber)*10.0f/((-3.5f)-(-4.1f))); else if(log_ber <= (-3.1f)) *quality = (MS_U16)(50.0f + ((-3.1f)-log_ber)*10.0f/((-3.1f)-(-3.5f))); else if(log_ber <= (-2.7f)) *quality = (MS_U16)(40.0f + ((-2.7f)-log_ber)*10.0f/((-2.7f)-(-3.1f))); else if(log_ber <= (-2.5f)) *quality = (MS_U16)(30.0f + ((-2.5f)-log_ber)*10.0f/((-2.5f)-(-2.7f))); else if(log_ber <= (-2.06f)) *quality = (MS_U16)(20.0f + ((-2.06f)-log_ber)*10.0f/((-2.06f)-(-2.5f))); //else if(log_ber <= (-2.05)) else { if (f_snr >= 27.2f) *quality = 20; else if (f_snr >= 25.1f) *quality = (MS_U16)(0.0f + (f_snr - 25.1f)*20.0f/(27.2f-25.1f)); else *quality = 0; } } else //256QAM { if(log_ber <= (-4.8f)) *quality = 100; else if(log_ber <= (-4.6f)) *quality = (MS_U16)(90.0f + ((-4.6f)-log_ber)*10.0f/((-4.6f)-(-4.8f))); else if(log_ber <= (-4.4f)) *quality = (MS_U16)(80.0f + ((-4.4f)-log_ber)*10.0f/((-4.4f)-(-4.6f))); else if(log_ber <= (-4.0f)) *quality = (MS_U16)(70.0f + ((-4.0f)-log_ber)*10.0f/((-4.0f)-(-4.4f))); else if(log_ber <= (-3.5f)) *quality = (MS_U16)(60.0f + ((-3.5f)-log_ber)*10.0f/((-3.5f)-(-4.0f))); else if(log_ber <= (-3.1f)) *quality = (MS_U16)(50.0f + ((-3.1f)-log_ber)*10.0f/((-3.1f)-(-3.5f))); else if(log_ber <= (-2.7f)) *quality = (MS_U16)(40.0f + ((-2.7f)-log_ber)*10.0f/((-2.7f)-(-3.1f))); else if(log_ber <= (-2.4f)) *quality = (MS_U16)(30.0f + ((-2.4f)-log_ber)*10.0f/((-2.4f)-(-2.7f))); else if(log_ber <= (-2.06f)) *quality = (MS_U16)(20.0f + ((-2.06f)-log_ber)*10.0f/((-2.06f)-(-2.4f))); //else if(log_ber <= (-2.05)) else { if (f_snr >= 29.6f) *quality = 20; else if (f_snr >= 27.3f) *quality = (MS_U16)(0.0f + (f_snr - 27.3f)*20.0f/(29.6f-27.3f)); else *quality = 0; } } } else { *quality = 0; } //DBG_GET_SIGNAL_DVBC(ULOGD("DEMOD","SNR = %f, QAM = %d, code Rate = %d\n", cn_rec, tps_cnstl, tps_cr)); ULOGD("DEMOD","BER = %8.3e\n", fber); ULOGD("DEMOD","Signal Quility = %d\n", *quality); return TRUE; } /**************************************************************************** Subject: To get the Cell ID Function: INTERN_DVBC_Get_CELL_ID Parmeter: point to return parameter cell_id Return: TRUE FALSE Remark: *****************************************************************************/ MS_BOOL INTERN_DVBC_Get_CELL_ID(MS_U16 *cell_id) { MS_BOOL status = true; MS_U8 value1 = 0; MS_U8 value2 = 0; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FDP_REG_BASE+0x2B, &value2); //TPS Cell ID [15:8] status &= MDrv_SYS_DMD_VD_MBX_ReadReg(FDP_REG_BASE+0x2A, &value1); //TPS Cell ID [7:0] *cell_id = ((MS_U16)value1<<8)|value2; return status; } /**************************************************************************** Subject: To get the DVBC Carrier Freq Offset Function: INTERN_DVBC_Get_FreqOffset Parmeter: Frequency offset (in KHz), bandwidth Return: E_RESULT_SUCCESS E_RESULT_FAILURE Remark: *****************************************************************************/ MS_BOOL INTERN_DVBC_Get_FreqOffset(float *pFreqOff, MS_U8 u8BW) { MS_U16 FreqB, config_Fc=0; float FreqCfo_offset,f_Fc; MS_U32 RegCfo_offset, Reg_Fc_over_Fs; MS_U8 reg = 0; MS_BOOL status = TRUE; // no use. u8BW = u8BW; ULOGD("DEMOD","INTERN_DVBC_Get_FreqOffset\n"); #if 1 // bank 2c 0x3d [0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE + 0x3A, 0x20); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(INNC_REG_BASE + 0x05, 0x80); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x43, ®); RegCfo_offset = reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x42, ®); RegCfo_offset = (RegCfo_offset<<8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x41, ®); RegCfo_offset = (RegCfo_offset<<8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x40, ®); RegCfo_offset = (RegCfo_offset<<8)|reg; // bank 2c 0x3d [0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE + 0x3A, 0x00); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(INNC_REG_BASE + 0x05, 0x00); #else // bank 2c 0x3d [0] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE+0x3d, ®_frz); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE+0x3d, reg_frz|0x01); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE2_REG_BASE + 0x75, ®); RegCfo_offset = reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE2_REG_BASE + 0x74, ®); RegCfo_offset = (RegCfo_offset<<8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE2_REG_BASE + 0x73, ®); RegCfo_offset = (RegCfo_offset<<8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(EQE2_REG_BASE + 0x72, ®); RegCfo_offset = (RegCfo_offset<<8)|reg; // bank 2c 0x3d [0] reg_bit_err_num_freeze reg_frz=reg_frz&(~0x01); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(EQE_REG_BASE+0x3d, reg_frz); #endif status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDF_REG_BASE + 0x5b, ®); Reg_Fc_over_Fs = reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDF_REG_BASE + 0x5a, ®); Reg_Fc_over_Fs = (Reg_Fc_over_Fs<<8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDF_REG_BASE + 0x59, ®); Reg_Fc_over_Fs = (Reg_Fc_over_Fs<<8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDF_REG_BASE + 0x58, ®); Reg_Fc_over_Fs = (Reg_Fc_over_Fs<<8)|reg; status &= MDrv_SYS_DMD_VD_MBX_ReadDSPReg(E_DMD_DVBC_CFG_FC_H, ®); config_Fc = reg; status &= MDrv_SYS_DMD_VD_MBX_ReadDSPReg(E_DMD_DVBC_CFG_FC_L, ®); config_Fc = (config_Fc<<8)|reg; f_Fc = (float)Reg_Fc_over_Fs/134217728.0f * 45473.0f; FreqCfo_offset = (MS_S32)(RegCfo_offset<<4)/16; FreqCfo_offset = FreqCfo_offset/0x8000000/8.0f; status &= INTERN_DVBC_GetCurrentSymbolRate(&FreqB); FreqCfo_offset = FreqCfo_offset * FreqB - (f_Fc-(float)config_Fc); //ULOGD("DEMOD","[dvbc]Freq_Offset = %f KHz, Reg_offset = 0x%lx, Reg_Fc_over_Fs=0x%lx, SR = %d KS/s, Fc = %f %d\n", // FreqCfo_offset,RegCfo_offset,Reg_Fc_over_Fs,FreqB,f_Fc,config_Fc); *pFreqOff = FreqCfo_offset; return status; } void INTERN_DVBC_Power_ON_OFF(MS_U8 bPowerOn) { bPowerOn = bPowerOn; } MS_BOOL INTERN_DVBC_Power_Save(void) { return TRUE; } /**************************************************************************** Subject: To get the current modulation type at the DVB-C Demod Function: INTERN_DVBC_GetCurrentModulationType Parmeter: pointer for return QAM type Return: TRUE FALSE Remark: *****************************************************************************/ MS_BOOL INTERN_DVBC_GetCurrentModulationType(DMD_DVBC_MODULATION_TYPE *pQAMMode) { MS_U8 u8Data=0; ULOGD("DEMOD","INTERN_DVBC_GetCurrentModulationType\n"); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x02, &u8Data); // MDrv_SYS_DMD_VD_MBX_ReadReg(EQE2_REG_BASE + 0xC4, &u8Data); switch(u8Data&0x07) { case 0: *pQAMMode = DMD_DVBC_QAM16; ULOGD("DEMOD","[dvbc]QAM=16\n"); return TRUE; break; case 1: *pQAMMode = DMD_DVBC_QAM32; ULOGD("DEMOD","[dvbc]QAM=32\n"); return TRUE; break; case 2: *pQAMMode = DMD_DVBC_QAM64; ULOGD("DEMOD","[dvbc]QAM=64\n"); return TRUE; break; case 3: *pQAMMode = DMD_DVBC_QAM128; ULOGD("DEMOD","[dvbc]QAM=128\n"); return TRUE; break; case 4: *pQAMMode = DMD_DVBC_QAM256; ULOGD("DEMOD","[dvbc]QAM=256\n"); return TRUE; break; default: *pQAMMode = DMD_DVBC_QAMAUTO; ULOGD("DEMOD","[dvbc]QAM=invalid\n"); return FALSE; } } /**************************************************************************** Subject: To get the current symbol rate at the DVB-C Demod Function: INTERN_DVBC_GetCurrentSymbolRate Parmeter: pointer pData for return Symbolrate Return: TRUE FALSE Remark: *****************************************************************************/ MS_BOOL INTERN_DVBC_GetCurrentSymbolRate(MS_U16 *u16SymbolRate) { MS_U8 tmp = 0; MS_U16 u16SymbolRateTmp = 0; // intp MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xd2, &tmp); u16SymbolRateTmp = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xd1, &tmp); u16SymbolRateTmp = (u16SymbolRateTmp<<8)|tmp; if (abs(u16SymbolRateTmp-6900)<2) { u16SymbolRateTmp=6900; } if (abs(u16SymbolRateTmp-6875)<2) { u16SymbolRateTmp=6875; } *u16SymbolRate = u16SymbolRateTmp; ULOGD("DEMOD","[dvbc]SR=%d\n",*u16SymbolRate); return TRUE; } /**************************************************************************** Subject: To get the current symbol rate offset at the DVB-C Demod Function: INTERN_DVBC_GetCurrentSymbolRate Parmeter: pointer pData for return Symbolrate offset Return: TRUE FALSE Remark: *****************************************************************************/ MS_BOOL INTERN_DVBC_GetCurrentSymbolRateOffset(MS_U16 *pData) { MS_U8 u8Data = 0, reg_frz = 0; MS_U32 u32Data = 0; // MS_S32 s32Data = 0; MS_BOOL status = TRUE; MS_U16 u16SymbolRate = 0; float f_symb_offset = 0.0f; // bank 26 0x03 [7] reg_bit_err_num_freeze status &= MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE+0x03, ®_frz); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(INNC_REG_BASE+0x03, reg_frz|0x80); // sel, SFO debug output. status &= MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE+0x2F, &u8Data); u32Data = u8Data; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE+0x2E, &u8Data); u32Data = (u32Data<<8)|u8Data; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE+0x2D, &u8Data); u32Data = (u32Data<<8)|u8Data; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE+0x2C, &u8Data); u32Data = (u32Data<<8)|u8Data; // bank 26 0x03 [7] reg_bit_err_num_freeze reg_frz=reg_frz&(~0x80); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(INNC_REG_BASE+0x03, reg_frz); // s32Data = (MS_S32)(u32Data<<8); ULOGD("DEMOD","[dvbc]u32_symb_offset = 0x%x\n",u32Data); status &= INTERN_DVBC_GetCurrentSymbolRate(&u16SymbolRate); // sfo = Reg*2^(-37)*FB/FS*1000000 (2^-28 * 1000000 = 0.003725) f_symb_offset = (float)((MS_S32)u32Data) * (1000000.0f/powf(2.0f, 37.0f)) * (float)u16SymbolRate/(float)DVBC_FS; *pData = (MS_U16)(f_symb_offset + 0.5f); ULOGD("DEMOD","[dvbc]sfo_offset = %d,%f\n",*pData, f_symb_offset); return status; } MS_BOOL INTERN_DVBC_Version(MS_U16 *ver) { MS_U8 status = true; MS_U8 tmp = 0; MS_U16 u16_INTERN_DVBC_Version; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xC1, &tmp); u16_INTERN_DVBC_Version = tmp; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xC2, &tmp); u16_INTERN_DVBC_Version = u16_INTERN_DVBC_Version<<8|tmp; *ver = u16_INTERN_DVBC_Version; return status; } MS_BOOL INTERN_DVBC_Show_Demod_Version(void) { MS_BOOL status = true; MS_U16 u16_INTERN_DVBC_Version; status &= INTERN_DVBC_Version(&u16_INTERN_DVBC_Version); ULOGD("DEMOD","[DVBC]Version = %x\n",u16_INTERN_DVBC_Version); return status; } #if (INTERN_DVBC_INTERNAL_DEBUG) MS_BOOL INTERN_DVBC_Show_AGC_Info(void) { MS_U8 tmp = 0; MS_U8 agc_k = 0,agc_ref = 0,d1_k = 0,d1_ref = 0,d2_k = 0,d2_ref = 0; MS_U16 if_agc_gain = 0,d1_gain = 0,d2_gain = 0; MS_U16 if_agc_err = 0; MS_BOOL status = TRUE; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x11,&agc_k); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x13,&agc_ref); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xB0,&d1_k); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xB1,&d1_ref); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xC0,&d2_k); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xC1,&d2_ref); // select IF gain to read status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x22, &tmp); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0x22, (tmp&0xF0)|0x03); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x25, &tmp); if_agc_gain = tmp; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x24, &tmp); if_agc_gain = (if_agc_gain<<8)|tmp; // select d1 gain to read. status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xb6, &tmp); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0xb6, (tmp&0xF0)|0x02); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xb9, &tmp); d1_gain = tmp; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xb8, &tmp); d1_gain = (d1_gain<<8)|tmp; // select d2 gain to read. status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xc6, &tmp); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0xc6, (tmp&0xF0)|0x02); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xc9, &tmp); d2_gain = tmp; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xc8, &tmp); d2_gain = (d2_gain<<8)|tmp; // select IF gain err to read status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x22, &tmp); status &= MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0x22, (tmp&0xF0)|0x00); status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x25, &tmp); if_agc_err = tmp; status &= MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x24, &tmp); if_agc_err = (if_agc_err<<8)|tmp; ULOGD("DEMOD","[dvbc]agc_k=0x%x, agc_ref=0x%x, d1_k=0x%x, d1_ref=0x%x, d2_k=0x%x, d2_ref=0x%x\n", agc_k,agc_ref,d1_k,d1_ref,d2_k,d2_ref); ULOGD("DEMOD","[dvbc]agc_g=0x%x, d1_g=0x%x, d2_g=0x%x, agc_err=0x%x\n",if_agc_gain,d1_gain,d2_gain,if_agc_err); return status; } void INTERN_DVBC_info(void) { MS_U32 fb_fs = 0, fc_fs = 0, tr_error = 0, crv = 0, intp = 0; MS_U8 qam,tmp = 0; MS_U8 fft_u8 = 0; MS_U16 fft_u16bw = 0; MS_U16 version = 0,packetErr = 0,quality = 0,symb_rate = 0,symb_offset = 0; float f_snr = 0,f_freq = 0; DMD_DVBC_MODULATION_TYPE QAMMode = 0; MS_U16 f_start = 0,f_end = 0; MS_U8 s0_count = 0; MS_U8 sc4 = 0,sc3 = 0; MS_U8 kp0, kp1, kp2, kp3,kp4, fmax, era_th; MS_U16 aci_e0,aci_e1,aci_e2,aci_e3; MS_U16 count = 0; MS_U16 fb_i_1,fb_q_1; MS_U8 e0,e1,e2,e3; MS_S16 reg_freq; float freq,mag; INTERN_DVBC_Version(&version); // fb_fs MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x53, &tmp); fb_fs = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x52, &tmp); fb_fs = (fb_fs<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x51, &tmp); fb_fs = (fb_fs<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x50, &tmp); fb_fs = (fb_fs<<8)|tmp; // fc_fs MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x57, &tmp); fc_fs = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x56, &tmp); fc_fs = (fc_fs<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x55, &tmp); fc_fs = (fc_fs<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x54, &tmp); fc_fs = (fc_fs<<8)|tmp; // crv MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x43, &tmp); crv = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x42, &tmp); crv = (crv<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x41, &tmp); crv = (crv<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x40, &tmp); crv = (crv<<8)|tmp; // tr_error MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE + 0x4E, &tmp); tr_error = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE + 0x4D, &tmp); tr_error = (tr_error<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(INNC_REG_BASE + 0x4C, &tmp); tr_error = (tr_error<<8)|tmp; // intp MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xD3, &tmp); intp = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xD2, &tmp); intp = (intp<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xD1, &tmp); intp = (intp<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0xD0, &tmp); intp = (intp<<8)|tmp; // fft info // intp MDrv_SYS_DMD_VD_MBX_ReadReg(TDE_REG_BASE + 0x93, &tmp); fft_u16bw = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDE_REG_BASE + 0x92, &tmp); fft_u16bw = (fft_u16bw<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDE_REG_BASE + 0x96, &tmp); fft_u8 = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x02, &tmp); qam = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE0, &tmp); f_start = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE1, &tmp); f_start = (f_start<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE2, &tmp); f_end = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE3, &tmp); f_end = (f_end<<8)|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE4, &tmp); s0_count = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xC3, &sc3); MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xC4, &sc4); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x04, &kp0); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x05, &kp1); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x06, &kp2); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x07, &kp3); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x08, &kp4); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x0B, &fmax); MDrv_SYS_DMD_VD_MBX_ReadReg(EQE_REG_BASE + 0x49, &era_th); MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0x81, 0x00); count = 0x400; while(count--); MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x85, &tmp); aci_e0 = tmp&0x0f; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x84, &tmp); aci_e0 = aci_e0<<8|tmp; MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0x81, 0x01); count = 0x400; while(count--); MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x85, &tmp); aci_e1 = tmp&0x0f; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x84, &tmp); aci_e1 = aci_e1<<8|tmp; MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0x81, 0x02); count = 0x400; while(count--); MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x85, &tmp); aci_e2 = tmp&0x0f; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x84, &tmp); aci_e2 = aci_e2<<8|tmp; // read aci coef MDrv_SYS_DMD_VD_MBX_WriteReg(TDP_REG_BASE + 0x81, 0x03); count = 0x400; while(count--); MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x85, &tmp); aci_e3 = tmp&0x0f; MDrv_SYS_DMD_VD_MBX_ReadReg(TDP_REG_BASE + 0x84, &tmp); aci_e3 = aci_e3<<8|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDE_REG_BASE + 0x13, &tmp); fb_i_1 = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDE_REG_BASE + 0x12, &tmp); fb_i_1 = fb_i_1<<8|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDE_REG_BASE + 0x15, &tmp); fb_q_1 = tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TDE_REG_BASE + 0x14, &tmp); fb_q_1 = fb_q_1<<8|tmp; MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE0, &e0); MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE1, &e1); MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE2, &e2); MDrv_SYS_DMD_VD_MBX_ReadReg(TOP_REG_BASE + 0xE3, &e3); reg_freq = (MS_S16)((MS_U16)e1)<<8|e0; freq = (float)reg_freq*45473.0/65536.0; mag = (float)(((MS_U16)e3)<<8|e2)/65536.0; INTERN_DVBC_GetPacketErr(&packetErr); INTERN_DVBC_GetSNR(&f_snr); INTERN_DVBC_Show_AGC_Info(); INTERN_DVBC_GetSignalQuality(&quality,NULL,0, 200.0f); INTERN_DVBC_Get_FreqOffset(&f_freq,8); INTERN_DVBC_GetCurrentSymbolRate(&symb_rate); INTERN_DVBC_GetCurrentSymbolRateOffset(&symb_offset); INTERN_DVBC_GetCurrentModulationType(&QAMMode); ULOGD("DEMOD","[MStar_1][1]0x%x,[2]0x%lx,[3]0x%lx,[4]0x%lx,[5]0x%lx,[6]0x%x,[7]%d\n",version,fb_fs,fc_fs,tr_error,crv,qam,packetErr); ULOGD("DEMOD","[MStar_2][1]%f,[2]0x%lx,[3]%d,[4]%f,[5]%d,[6]%d,[7]%d\n",f_snr,intp,quality,f_freq,symb_rate,symb_offset,packetErr); ULOGD("DEMOD","[Mstar_3][1]0x%x,[2]0x%x,[3]0x%x,[4]0x%x,[5]%d,[6]0x%x,[7]0x%x\n",fft_u16bw,fft_u8,f_end,f_start,s0_count,sc3,sc4); ULOGD("DEMOD","[Mstar_4][1]0x%x,[2]0x%x,[3]0x%x,[4]0x%x,[5]0x%x,[6]0x%x,[7]0x%x\n",kp0,kp1,kp2,kp3,kp4,fmax,era_th); ULOGD("DEMOD","[Mstar_5][1]0x%x,[2]0x%x,[3]0x%x,[4]0x%x,[5]0x%x,[6]0x%x,[7]0x%x\n",aci_e0,aci_e1,aci_e2,aci_e3,fb_i_1,fb_q_1,era_th); ULOGD("DEMOD","[Mstar_6][1]%f,[2]%f,[3]0x%x,[4]0x%x,[5]0x%x,[6]0x%x,[7]0x%x\n",freq,mag,aci_e2,aci_e3,fb_i_1,fb_q_1,era_th); return; } #endif /*********************************************************************************** Subject: read register Function: MDrv_1210_IIC_Bypass_Mode Parmeter: Return: Remark: ************************************************************************************/ //void MDrv_1210_IIC_Bypass_Mode(MS_BOOL enable) //{ // UNUSED(enable); // if (enable) // MDrv_SYS_DMD_VD_MBX_WriteReg(0x8010, 0x10); // IIC by-pass mode on // else // MDrv_SYS_DMD_VD_MBX_WriteReg(0x8010, 0x00); // IIC by-pass mode off //}