/* * ddbridge-mci.h: Digital Devices micro code interface * * Copyright (C) 2017-2018 Digital Devices GmbH * Marcus Metzler * Ralph Metzler * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * version 2 only, as published by the Free Software Foundation. * * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * * You should have received a copy of the GNU General Public License * along with this program; if not, point your browser to * http://www.gnu.org/copyleft/gpl.html */ #ifndef _DDBRIDGE_MCI_H_ #define _DDBRIDGE_MCI_H_ #define SX8_TSINPUT (0x280) #define MIC_CONTROL (0x500) #define MIC_PROGMEM_OLD (0x4000) #define MIC_PROGMEM_OLD_SIZE (0x4000) #define MIC_PROGMEM (0x8000) #define MIC_PROGMEM_SIZE (0x8000) #define MIC_DATAMEM (0x8000) #define MIC_DATAMEM_SIZE (0x2000) #define MIC_INTERFACE_IN (0x0600) #define MIC_INTERFACE_OUT (0x0680) #define MIC_INTERFACE_VER (0x06F0) #define MCI_CONTROL (0x500) #define MCI_COMMAND (0x600) #define MCI_RESULT (0x680) #define MCI_COMMAND_SIZE (0x80) #define MCI_RESULT_SIZE (0x80) #define MCI_CONTROL_START_COMMAND (0x00000001) #define MCI_CONTROL_ENABLE_DONE_INTERRUPT (0x00000002) #define MCI_CONTROL_RESET (0x00008000) #define MCI_CONTROL_READY (0x00010000) #define SX8_TSCONFIG (0x280) #define SX8_TSCONFIG_MODE_MASK (0x00000003) #define SX8_TSCONFIG_MODE_OFF (0x00000000) #define SX8_TSCONFIG_MODE_NORMAL (0x00000001) #define SX8_TSCONFIG_MODE_IQ (0x00000003) /* * IQMode only vailable on MaxSX8 on a single tuner * * IQ_MODE_SAMPLES * sampling rate is 1550/24 MHz (64.583 MHz) * channel agc is frozen, to allow stitching the FFT results together * * IQ_MODE_VTM * sampling rate is the supplied symbolrate * channel agc is active * * in both cases down sampling is done with a RRC Filter (currently fixed to alpha = 0.05) * which causes some (ca 5%) aliasing at the edges from outside the spectrum */ #define SX8_TSCONFIG_TSHEADER (0x00000004) #define SX8_TSCONFIG_BURST (0x00000008) #define SX8_TSCONFIG_BURSTSIZE_MASK (0x00000030) #define SX8_TSCONFIG_BURSTSIZE_2K (0x00000000) #define SX8_TSCONFIG_BURSTSIZE_4K (0x00000010) #define SX8_TSCONFIG_BURSTSIZE_8K (0x00000020) #define SX8_TSCONFIG_BURSTSIZE_16K (0x00000030) /* additional TS input control bits on MaxSX8 DD01:0009 */ #define TS_INPUT_CONTROL_SIZEMASK (0x00000030) #define TS_INPUT_CONTROL_SIZE188 (0x00000000) #define TS_INPUT_CONTROL_SIZE192 (0x00000010) #define TS_INPUT_CONTROL_SIZE196 (0x00000020) /********************************************************/ #define MCI_DEMOD_STOPPED (0) #define MCI_DEMOD_WAIT_SIGNAL (2) #define MCI_DEMOD_TIMEOUT (14) #define MCI_DEMOD_LOCKED (15) #define SX8_DEMOD_IQ_MODE (1) #define SX8_DEMOD_WAIT_MATYPE (3) #define M4_DEMOD_WAIT_TS (6) #define M4_DEMOD_C2SCAN (16) #define MCI_STATUS_OK (0x00) #define MCI_STATUS_UNSUPPORTED (0x80) #define MCI_STATUS_INVALID_PARAMETER (0xFC) #define MCI_STATUS_RETRY (0xFD) #define MCI_STATUS_NOT_READY (0xFE) #define MCI_STATUS_ERROR (0xFF) #define MCI_CMD_STOP (0x01) #define MCI_CMD_GETSTATUS (0x02) #define MCI_CMD_GETSIGNALINFO (0x03) //#define MCI_CMD_RFPOWER (0x04) #define MCI_CMD_SEARCH_DVBS (0x10) #define MCI_CMD_SEARCH_ISDBS (0x11) #define MCI_CMD_SEARCH_DVBC (0x20) #define MCI_CMD_SEARCH_DVBT (0x21) #define MCI_CMD_SEARCH_DVBT2 (0x22) #define MCI_CMD_SEARCH_DVBC2 (0x23) #define MCI_CMD_SEARCH_ISDBT (0x24) #define MCI_CMD_SEARCH_ISDBC (0x25) #define MCI_CMD_SEARCH_J83B (0x26) #define MCI_CMD_GET_IQSYMBOL (0x30) #define MCI_BANDWIDTH_UNKNOWN (0) #define MCI_BANDWIDTH_1_7MHZ (1) #define MCI_BANDWIDTH_5MHZ (5) #define MCI_BANDWIDTH_6MHZ (6) #define MCI_BANDWIDTH_7MHZ (7) #define MCI_BANDWIDTH_8MHZ (8) #define SX8_CMD_INPUT_ENABLE (0x40) #define SX8_CMD_INPUT_DISABLE (0x41) #define SX8_CMD_START_IQ (0x42) #define SX8_CMD_STOP_IQ (0x43) #define SX8_CMD_ENABLE_IQOUTPUT (0x44) #define SX8_CMD_DISABLE_IQOUTPUT (0x45) #define M4_CMD_GET_L1INFO (0x50) #define M4_CMD_GET_IDS (0x51) #define M4_CMD_GET_DVBT_TPS (0x52) #define MCI_CMD_GET_BBHEADER (0x53) #define M4_CMD_GET_BBHEADER (MCI_CMD_GET_BBHEADER) #define M4_CMD_GET_ISDBT_TMCC (0x54) #define M4_CMD_GET_ISDBS_TMCC (0x55) #define M4_CMD_GET_ISDBC_TSMF (0x56) #define M4_L1INFO_SEL_PRE (0) #define M4_L1INFO_SEL_DSINFO (1) #define M4_L1INFO_SEL_PLPINFO (2) #define M4_L1INFO_SEL_PLPINFO_C (3) #define M4_L1INFO_SEL_SETID (0x80) #define MCI_BANDWIDTH_EXTENSION (0x80) // currently used only for J83B in Japan #define M4_MODE_DVBSX (2) #define M4_MODE_DVBC (3) #define M4_MODE_DVBT (4) #define M4_MODE_DVBT2 (5) #define M4_MODE_DVBC2 (6) #define M4_MODE_J83B (7) #define M4_MODE_ISDBT (8) #define M4_MODE_ISDBC (9) #define M4_MODE_ISDBS (10) #define M4_DVBC_CONSTELLATION_16QAM (0) #define M4_DVBC_CONSTELLATION_32QAM (1) #define M4_DVBC_CONSTELLATION_64QAM (2) // also valid for J83B and ISDB-C #define M4_DVBC_CONSTELLATION_128QAM (3) #define M4_DVBC_CONSTELLATION_256QAM (4) // also valid for J83B and ISDB-C #define M4_SIGNALINFO_FLAG_CHANGE (0x01) #define M4_SIGNALINFO_FLAG_EWS (0x02) #define SX8_ROLLOFF_25 1 #define SX8_ROLLOFF_20 2 #define SX8_ROLLOFF_15 5 #define SX8_ROLLOFF_10 3 #define SX8_ROLLOFF_05 4 #define MCI_SUCCESS(status) ((status & MCI_STATUS_UNSUPPORTED) == 0) /********************************************************/ struct mci_command { union { u32 command_word; struct { u8 command; u8 tuner; u8 demod; u8 output; }; }; union { u32 params[31]; struct { u8 flags; /* Bit 0: DVB-S Enabled, 1: DVB-S2 Enabled, 6: FrequencyRange, 7: InputStreamID */ u8 s2_modulation_mask; /* Bit 0 : QPSK, 1: 8PSK/8APSK, 2 : 16APSK, 3: 32APSK, 4: 64APSK, 5: 128APSK, 6: 256APSK */ u8 rsvd1; u8 retry; u32 frequency; u32 symbol_rate; u8 input_stream_id; u8 rsvd2[3]; u32 scrambling_sequence_index; u32 frequency_range; } dvbs2_search; struct { u8 flags; /* Bit 0: 0 = TSID is Transport Stream ID, 1 = TSID is relative stream number */ u8 rsvd1[2]; u8 retry; u32 frequency; u32 rsvd2; u16 rsvd3; u16 tsid; } isdbs_search; struct { u8 flags; u8 bandwidth; u8 rsvd1; u8 retry; u32 frequency; } dvbc_search; struct { u8 flags; /* Bit 0: LP Stream */ u8 bandwidth; u8 rsvd1; u8 retry; u32 frequency; } dvbt_search; struct { u8 flags; /* Bit 0: T2 Lite Profile, 7: PLP, */ u8 bandwidth; u8 rsvd1; u8 retry; u32 frequency; u32 reserved; u8 plp; u8 rsvd2[3]; } dvbt2_search; struct { u8 flags; u8 bandwidth; u8 rsvd1; u8 retry; u32 frequency; u32 reserved; u8 plp; u8 data_slice; u8 rsvd2[2]; } dvbc2_search; struct { u8 flags; u8 bandwidth; u8 rsvd1; u8 retry; u32 frequency; } isdbt_search; struct { u8 flags; /* Bit 0: 0 = TSID is Transport Stream ID, 1 = TSID is relative stream number */ /* Bit 2..1: 0 = force single, 1 = force multi, 2 = auto detect */ u8 bandwidth; u8 rsvd1; u8 retry; u32 frequency; u32 rsvd2; u16 onid; u16 tsid; } isdbc_search; struct { u8 flags; u8 bandwidth; u8 rsvd1; u8 retry; u32 frequency; } j83b_search; struct { u8 flags; // Bit 0 : 1 = short info (1st 4 Bytes) } get_signalinfo; struct { u8 tap; u8 rsvd; u16 point; } get_iq_symbol; struct { uint8_t flags; /* Bit 0 : 0 = VTM/SDR, 1 = SCAN, Bit 1: 1 = Disable AGC, Bit 2: 1 = Set Gain. */ uint8_t roll_off; uint8_t rsvd1; uint8_t rsvd2; uint32_t frequency; uint32_t symbol_rate; /* Only in VTM/SDR mode, SCAN Mode uses exactly 1550/24 MSymbols/s.*/ uint8_t gain; /* Gain in 0.25 dB Steps */ /* Frequency, symbolrate and gain can be schanged while running */ } sx8_start_iq; struct { uint8_t flags; /* Bit 0:1 Preamp Mode; 0 = Preamp AGC, 1 == Minimum (~ -17dB) , 2 = Medium, 3 = Maximum gain {~ 15dB} Bit 2: Bypass Input LNA (6 dB less gain) (Note this is after Preamp) Bit 4: Set RF Gain Bit 5: Freeze RF Gain (Turn AGC off at current gain, only when already enabled) Bit 7: Optimize RF Gain and freeze for FFT */ uint8_t rf_gain; /* 0 .. 50 dB */ } sx8_input_enable; struct { u8 offset; // Offset into list, must be multiple of 64 u8 select; // 0 = Slices, 1 = PLPs (C2 Only) u8 data_slice; // DataSlice to get PLPList (C2 Only) } get_ids; struct { u8 select; // 0 = Base, 1 = DataSilce, 2 = PLP, Bit 7: Set new ID u8 id; // DataSliceID, PLPId } get_l1_info; struct { u8 select; // 0 = Data PLP, 1 = Common PLP, only DVB-T2 and DVB-C2 } get_bb_header; }; }; struct mci_result { union { u32 status_word; struct { u8 status; u8 mode; u16 time; }; }; union { u32 result[27]; struct { u8 Rsvd0[3]; u8 Flags; u32 frequency; // actual frequency in Hz u32 rsvd1; s16 channel_power; // channel power in dBm x 100 s16 rsvd2; s16 signal_to_noise; // SNR in dB x 100, Note: negativ values are valid in DVB-S2 s16 rsvd3; u32 rsvd4; u32 ber_numerator; /* Bit error rate: PreRS in DVB-S, PreBCH in DVB-S2X */ u32 ber_denominator; u32 ber_rsvd1; // Place holder for modulation bit error rate u32 ber_rsvd2; } common_signal_info; struct { u8 standard; /* 1 = DVB-S, 2 = DVB-S2X */ u8 pls_code; /* PLS code for DVB-S2/S2X, puncture rate for DVB-S */ u8 roll_off; /* 2-0: rolloff, 7: spectrum inversion */ u8 flags; u32 frequency; /* actual frequency in Hz */ u32 symbol_rate; /* actual symbolrate in Hz */ s16 channel_power; /* channel power in dBm x 100 */ s16 band_power; /*/ band power in dBm x 100 */ s16 signal_to_noise; /* SNR in dB x 100, Note: negativ values are valid in DVB-S2 */ s16 rsvd2; u32 packet_errors; /* Counter for packet errors. (set to 0 on Start command) */ u32 ber_numerator; /* Bit error rate: PreRS in DVB-S, PreBCH in DVB-S2X */ u32 ber_denominator; } dvbs2_signal_info; struct { u8 constellation; u8 rsvd0[2]; u8 flags; u32 frequency; /* actual frequency in Hz */ u32 symbol_rate; /* actual symbolrate in Hz */ s16 channel_power; /* channel power in dBm x 100 */ s16 band_power; /* band power in dBm x 100 */ s16 signal_to_noise; /* SNR in dB x 100, Note: negativ values are valid in DVB-S2 */ s16 rsvd2; u32 packet_errors; /* Counter for packet errors. (set to 0 on Start command) */ u32 ber_numerator; /* Bit error rate: PreRS */ u32 ber_denominator; } dvbc_signal_info; struct { u8 modulation1; // bit 7..6: Constellation, bit 5..3 Hierachy, bit 2..0 CodeRate High u8 modulation2; // bit 7..5: CodeRate Low, bit 4..3 Guard Interval, bit 2..1 FFT Mode u8 Rsvd0; u8 Flags; u32 frequency; /* actual frequency in Hz */ u32 rsvd1; s16 channel_power; /* channel power in dBm x 100 */ s16 band_power; /* band power in dBm x 100 */ s16 signal_to_noise; /* SNR in dB x 100, Note: negativ values are valid in DVB-S2 */ s16 rsvd2; u32 packet_errors; /* Counter for packet errors. (set to 0 on Start command) */ u32 ber_numerator; /* Bit error rate: PreRS */ u32 ber_denominator; } dvbt_signal_info; struct { u8 rsvd0[3]; u8 flags; u32 frequency; /* actual frequency in Hz */ u32 rsvd1; s16 channel_power; /* channel power in dBm x 100 */ s16 band_power; /* band power in dBm x 100 */ s16 signal_to_noise; /* SNR in dB x 100, Note: negativ values are valid in DVB-S2 */ s16 rsvd2; u32 packet_errors; /* Counter for packet errors. (set to 0 on Start command) */ u32 ber_numerator; /* Bit error rate: PreRS */ u32 ber_denominator; } dvbt2_signal_info; struct { u8 rsvd0[3]; u8 flags; u32 frequency; // actual frequency in Hz u32 rsvd1; // s16 channel_power; // channel power in dBm x 100 s16 band_power; // band power in dBm x 100 s16 signal_to_noise; // SNR in dB x 100, Note: negativ values are valid in DVB-S2 s16 rsvd2; u32 packet_errors; // Counter for packet errors. (set to 0 on Start command) u32 ber_numerator; // Bit error rate: PreBCH u32 ber_denominator; } dvbc2_signal_info; struct { u8 rsvd0[3]; u8 flags; u32 frequency; // actual frequency in Hz u32 rsvd1; // s16 channel_power; // channel power in dBm x 100 s16 band_power; // band power in dBm x 100 s16 signal_to_noise; // SNR in dB x 100, Note: negativ values are valid in DVB-S2 s16 rsvd2; u32 packet_errors; // Counter for packet errors. (set to 0 on Start command) u32 ber_numerator; // Bit error rate: PreRS Segment A u32 ber_denominator; u32 ber_rsvd1; // Place holder for modulation bit error rate u32 ber_rsvd2; u32 ber_numeratorB; // Bit error rate: PreRS Segment B u32 ber_numeratorC; // Bit error rate: PreRS Segment C } isdbt_signal_info; struct { u8 Constellation; u8 Rsvd0[2]; u8 Flags; u32 Frequency; // actual frequency in Hz u32 SymbolRate; // actual symbolrate in Hz s16 ChannelPower; // channel power in dBm x 100 s16 BandPower; // band power in dBm x 100 s16 SignalToNoise; // SNR in dB x 100, Note: negativ values are valid in DVB-S2 s16 Rsvd2; u32 PacketErrors; // Counter for packet errors. (set to 0 on Start command) u32 BERNumerator; // Bit error rate: PreRS in DVB-S, PreBCH in DVB-S2X u32 BERDenominator; } ISDBC_SignalInfo; struct { u8 Constellation; u8 Interleaving; u8 Rsvd0; u8 Flags; u32 Frequency; // actual frequency in Hz u32 SymbolRate; // actual symbolrate in Hz s16 ChannelPower; // channel power in dBm x 100 s16 BandPower; // band power in dBm x 100 s16 SignalToNoise; // SNR in dB x 100, Note: negativ values are valid in DVB-S2 s16 Rsvd2; u32 PacketErrors; // Counter for packet errors. (set to 0 on Start command) u32 BERNumerator; // Bit error rate: PreRS in DVB-S, PreBCH in DVB-S2X u32 BERDenominator; } J83B_SignalInfo; struct { s16 i; s16 q; } iq_symbol; struct { u8 TPSInfo[7]; // uint16_t TPS_CellID; // Cell Identifier } DVBT_TPSInfo; struct { struct { u8 Type; u8 BWExtension; u8 S1; u8 S2; u8 L1RepetitionFlag; u8 GuardInterval; u8 PAPR; u8 L1Mod; u8 L1Cod; u8 L1FECType; u8 L1PostSize[3]; u8 L1PostInfoSize[3]; u8 PilotPattern; u8 TXIDAvailabilty; u8 CellID[2]; u8 NetworkID[2]; u8 T2SystemID[2]; u8 NumT2Frames; u8 NumDataSymbols[2]; u8 RegenFlag; u8 L1PostExtension; u8 NumRF; u8 CurrentRFIndex; u8 T2Version_PostScrambled_BaseLite_Rsvd[2]; // 4,1,1,4 bit u8 CRC32[4]; } DVBT2_L1Pre; struct { u8 SubSlicesPerFrame[2]; u8 NumPLP; u8 NumAux; u8 AuxConfigRFU; u8 RFIndex; u8 Frequency[4]; u8 FEFType; u8 FEFLength[3]; u8 FEFInterval; } DVBT2_L1Post; } DVBT2_L1Info; struct { u8 PLPID; u8 Type; u8 PayloadType; u8 FFFlag; u8 FirstRFIndex; u8 FirstFrameIndex; u8 GroupID; u8 Cod; u8 Mod; u8 Rotation; u8 FECType; u8 NumBlocksMax[2]; u8 FrameInterval; u8 TimeILLength; u8 TimeILType; u8 InBandAFlag; u8 InBandBFlag_Rsvd1_Mode_StaticFlag_StaticPaddingFlag[2]; // 1,11,2,1,1 } DVBT2_PLPInfo; struct { u8 NetworkID[2]; u8 C2SystemID[2]; u8 StartFrequency[3]; u8 C2BandWidth[2]; u8 GuardInterval; u8 C2FrameLength[2]; u8 L1P2ChangeCounter; u8 NumDataSlices; u8 NumNotches; struct { u8 Start[2]; u8 Width[2]; u8 Reserved3; } NotchData[15]; u8 ReservedTone; u8 Reserved4[2]; // EWS 1 bit, C2_Version 4 bit, Rsvd 11 bit } DVBC2_L1Part2; struct { u8 NumIDs; u8 Offset; u8 IDs[64]; } DVBC2_IDList; struct { u8 SliceID; u8 TunePosition[2]; u8 OffsetLeft[2]; u8 OffsetRight[2]; u8 TIDepth; u8 Type; u8 FECHeaderType; u8 ConstConf; u8 LeftNotch; u8 NumPLP; u8 Reserved2; } DVBC2_SliceInfo; struct { u8 PLPID; u8 Bundled; u8 Type; u8 PayloadType; u8 GroupID; u8 Start[2]; u8 FECType; u8 Mod; u8 Cod; u8 PSISIReprocessing; u8 TransportstreamID[2]; u8 OrginalNetworkID[2]; u8 Reserved1; } DVBC2_PLPInfo; struct { u8 Valid; u8 MATYPE_1; u8 MATYPE_2; u8 UPL[2]; u8 DFL[2]; u8 SYNC; u8 SYNCD[2]; u8 rsvd; u8 ISSY[3]; u8 min_input_stream_id; u8 max_input_stream_id; } BBHeader; struct { u8 Mode; // FFT Mode 1,2,3 u8 GuardInterval; // 1/32, 1/16, 1/8, /14 u8 TMCCInfo[13]; // TMCC B20 - B121, byte 0 bit 7: B20, byte 12 bit 2: B121 } ISDBT_TMCCInfo; struct { u8 Change; // 5 bits, increments with every change struct { u8 ModCod; // 4 bits u8 NumSlots; // 6 bits } Mode[4]; u8 RelTSID[24]; // bit 6..4 Relative TSID for slot i*2 + 1, bit 2..0 Relative TSID for slot i*2 + 2 struct { u8 highByte; u8 lowByte; } TSID[8]; u8 Flags; // Bit 5: EWS flag, bit 4: Site Diversity flag, bit 3..1: Site Diversity information, bit 0: Extension flag u8 Extension[8]; // 61 bits, right aligned } ISDBS_TMCCInfo; }; u32 version[3]; u32 version_rsvd; u8 version_major; u8 version_minor; u8 version_sub; }; /* Helper Macros */ /* DVB-T2 L1-Pre Signalling Data ( ETSI EN 302 755 V1.4.1 Chapter 7.2.2 ) */ #define L1PRE_TYPE(p) ((p)[0] & 0xFF) #define L1PRE_BWT_EXT(p) ((p)[1] & 0x01) #define L1PRE_S1(p) ((p)[2] & 0x07) #define L1PRE_S2(p) ((p)[3] & 0x0F) #define L1PRE_L1_REPETITION_FLAG(p) ((p)[4] & 0x01) #define L1PRE_GUARD_INTERVAL(p) ((p)[5] & 0x07) #define L1PRE_PAPR(p) ((p)[6] & 0x0F) #define L1PRE_L1_MOD(p) ((p)[7] & 0x0F) #define L1PRE_L1_COD(p) ((p)[8] & 0x03) #define L1PRE_L1_FEC_TYPE(p) ((p)[9] & 0x03) #define L1PRE_L1_POST_SIZE(p) (((u32)((p)[10] & 0x03) << 16) | ((u32)(p)[11] << 8) | (p)[12]) #define L1PRE_L1_POST_INFO_SIZE(p) (((u32)((p)[13] & 0x03) << 16) | ((u32)(p)[14] << 8) | (p)[15]) #define L1PRE_PILOT_PATTERN(p) ((p)[16] & 0x0F) #define L1PRE_TX_ID_AVAILABILITY(p) ((p)[17] & 0xFF) #define L1PRE_CELL_ID(p) (((u16)(p)[18] << 8) | (p)[19]) #define L1PRE_NETWORK_ID(p) (((u16)(p)[20] << 8) | (p)[21]) #define L1PRE_T2_SYSTEM_ID(p) (((u16)(p)[22] << 8) | (p)[23]) #define L1PRE_NUM_T2_FRAMES(p) ((p)[24] & 0xFF) #define L1PRE_NUM_DATA_SYMBOLS(p) (((u16)((p)[25] & 0x0F) << 8) | (p)[26]) #define L1PRE_REGEN_FLAG(p) ((p)[27] & 0x07) #define L1PRE_L1_POST_EXTENSION(p) ((p)[28] & 0x01) #define L1PRE_NUM_RF(p) ((p)[29] & 0x07) #define L1PRE_CURRENT_RF_IDX(p) ((p)[30] & 0x07) #define L1PRE_T2_VERSION(p) ((((p)[31] & 0x03) << 2) | (((p)[32] & 0xC0) >> 6)) #define L1PRE_L1_POST_SCRAMBLED(p) (((p)[32] & 0x20) >> 5) #define L1PRE_T2_BASE_LITE(p) (((p)[32] & 0x10) >> 4) /* DVB-T2 L1-Post Signalling Data ( ETSI EN 302 755 V1.4.1 Chapter 7.2.3 ) */ #define L1POST_SUB_SLICES_PER_FRAME(p) (((u16)(p)[ 0] & 0x7F) | (p)[ 1]) #define L1POST_NUM_PLP(p) ((p)[2] & 0xFF) #define L1POST_NUM_AUX(p) ((p)[3] & 0x0F) #define L1POST_AUX_CONFIG_RFU(p) ((p)[4] & 0xFF) #define L1POST_RF_IDX(p) ((p)[5] & 0x07) #define L1POST_FREQUENCY(p) (((u32)(p)[6] << 24) | ((u32)(p)[7] << 16) | ((u32)(p)[8] << 8) | (p)[9]) #define L1POST_FEF_TYPE(p) ((p)[10] & 0x0F) #define L1POST_FEF_LENGTH(p) (((u32)(p)[11] << 16) | ((u32)(p)[12] << 8) | (p)[13]) #define L1POST_FEF_INTERVAL(p) ((p)[14] & 0xFF) /* Repeated for each PLP, */ /* Hardware is restricted to retrieve only values for current data PLP and common PLP */ #define L1POST_PLP_ID(p) ((p)[0] & 0xFF) #define L1POST_PLP_TYPE(p) ((p)[1] & 0x07) #define L1POST_PLP_PAYLOAD_TYPE(p) ((p)[2] & 0x1F) #define L1POST_FF_FLAG(p) ((p)[3] & 0x01) #define L1POST_FIRST_RF_IDX(p) ((p)[4] & 0x07) #define L1POST_FIRST_FRAME_IDX(p) ((p)[5] & 0xFF) #define L1POST_PLP_GROUP_ID(p) ((p)[6] & 0xFF) #define L1POST_PLP_COD(p) ((p)[7] & 0x07) #define L1POST_PLP_MOD(p) ((p)[8] & 0x07) #define L1POST_PLP_ROTATION(p) ((p)[9] & 0x01) #define L1POST_PLP_FEC_TYPE(p) ((p)[10] & 0x03) #define L1POST_PLP_NUM_BLOCKS_MAX(p) (((u16)((p)[11] & 0x03) << 8) | (p)[12]) #define L1POST_FRAME_INTERVAL(p) ((p)[13] & 0xFF) #define L1POST_TIME_IL_LENGTH(p) ((p)[14] & 0xFF) #define L1POST_TIME_IL_TYPE(p) ((p)[15] & 0x01) #define L1POST_IN_BAND_A_FLAG(p) ((p)[16] & 0x01) #define L1POST_IN_BAND_B_FLAG(p) (((p)[17] >> 7) & 0x01) #define L1POST_RESERVED_1(p) (((u16)((p)[17] & 0x7F) << 4) | ((p)[18] & 0xF0) >> 4) #define L1POST_PLP_MODE(p) (((p)[18] >> 2) & 0x03) #define L1POST_STATIC_FLAG(p) (((p)[18] >> 1) & 0x01) #define L1POST_STATIC_PADDING_FLAG(p) (((p)[18] >> 1) & 0x01) struct mci_base { struct list_head mci_list; void *key; struct ddb_link *link; struct completion completion; struct i2c_adapter *i2c; struct mutex i2c_lock; struct mutex tuner_lock; struct mutex mci_lock; int count; int type; }; struct mci { struct ddb_io *input; struct mci_base *base; struct dvb_frontend fe; int nr; int demod; int tuner; struct mci_result signal_info; }; struct mci_cfg { int type; struct dvb_frontend_ops *fe_ops; u32 base_size; u32 state_size; int (*init)(struct mci *mci); int (*base_init)(struct mci_base *mci_base); }; int ddb_mci_cmd(struct mci *state, struct mci_command *command, struct mci_result *result); int ddb_mci_cmd_raw(struct mci *state, struct mci_command *command, u32 command_len, struct mci_result *result, u32 result_len); int ddb_mci_config(struct mci *state, u32 config); int ddb_mci_get_status(struct mci *mci, struct mci_result *res); int ddb_mci_get_snr(struct dvb_frontend *fe); int ddb_mci_get_info(struct mci *mci); int ddb_mci_get_strength(struct dvb_frontend *fe); void ddb_mci_proc_info(struct mci *mci, struct dtv_frontend_properties *p); #endif