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view gsm-fw/L1/include/l1_msgty.h @ 588:1c0033c2fe33
gsm-fw/bsp/abb+spi/abb*.c: formatting fixes (line length and tabs)
author | Michael Spacefalcon <msokolov@ivan.Harhan.ORG> |
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date | Sun, 17 Aug 2014 00:35:56 +0000 |
parents | c87f2e4dc391 |
children |
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/************* Revision Controle System Header ************* * GSM Layer 1 software * L1_MSGTY.H * * Filename l1_msgty.h * Copyright 2003 (C) Texas Instruments * ************* Revision Controle System Header *************/ /* channels types */ #define L2_CHANNEL_SACCH 1 #define L2_CHANNEL_SDCCH 2 #define L2_CHANNEL_FACCH_H 3 #define L2_CHANNEL_FACCH_F 4 #define L2_CHANNEL_CCCH 5 #define L2_CHANNEL_NBCCH 6 #define L2_CHANNEL_PCH 7 #define L2_CHANNEL_EPCH 8 #define L2_CHANNEL_CBCH 9 #define L2_CHANNEL_EBCCH 10 /****************************************************************/ /* Structure definition for L1S <-> DATA ADAPTOR data blocks */ /* TCH/9.6 -> 30 bytes */ /* TCH/4.8 -> 15 bytes */ /* TCH/2.4 -> 9 bytes */ /****************************************************************/ typedef struct { UWORD8 A[30]; } T_DATA_FRAME; /****************************************************************/ /* Structure definition for L1A <-> MMI messages */ /****************************************************************/ typedef struct { UWORD8 tx_flag; UWORD8 traffic_period; UWORD8 idle_period; } T_MMI_ADC_REQ; /****************************************************************/ /* Structure definition for L1S <-> L1A messages */ /****************************************************************/ typedef T_PH_DATA_IND T_L1_BCCH_INFO; typedef T_PH_DATA_IND T_L1_CCCH_INFO; /****************************************************************/ /* Structure definition for new L3 <-> L1 messages */ /****************************************************************/ #if (OP_L1_STANDALONE == 1) /* Message used for hardware dynamic configuration */ typedef struct { UWORD8 num_of_clock_cfg; // Dynamic clock configuration index } T_TST_HW_CONFIG_REQ; #endif // OP_L1_STANDALONE /* Message used for software dynamic configuration */ typedef struct { UWORD8 ids_enable; // activation of IDS module T_FACCH_TEST_PARAMS facch_test; } T_TST_SW_CONFIG_REQ; typedef struct { UWORD32 mf51_fn; } T_MPHC_START_CBCH_READING; typedef struct { T_RXLEV_MEAS A[8]; UWORD8 nbr_of_carriers; WORD8 s_rxlev; UWORD8 ba_id; //added for Enhanced RSSI UWORD16 qual_acc_idle; // accumulated rxqual meas. on different channels in Idle mode.= error bits UWORD32 qual_nbr_meas_idle; // accumulated rxqual meas. on different channels in Idle mode.= total number of bits decoded } T_MPHC_RXLEV_PERIODIC_IND; typedef struct { TC_CHAN_LIST chan_list; UWORD8 num_of_chans; UWORD8 ba_id; UWORD8 next_radio_freq_measured; // index of first radio_freq to be measured } T_MPHC_RXLEV_PERIODIC_REQ; typedef struct { UWORD16 radio_freq; // carrier id. } T_MPHC_NCELL_FB_SB_READ; typedef struct { UWORD16 radio_freq; // carrier id. } T_MPHC_START_BCCH_READING; typedef struct { UWORD16 radio_freq; // carrier id. UWORD32 fn_offset; // offset between fn of this NCELL and the SCELL fn. UWORD32 time_alignmt; // time alignment. UWORD8 bsic; // BSIC. UWORD16 si_bit_map; // System Info. bit map. } T_MPHC_NCELL_BCCH_READ; typedef struct { UWORD32 fn; UWORD8 channel_request; } T_MPHC_RA_CON; typedef struct { T_CHANNEL_DESCRIPTION channel_desc; UWORD8 timing_advance; T_MOBILE_ALLOCATION frequency_list; T_STARTING_TIME starting_time; T_MOBILE_ALLOCATION frequency_list_bef_sti; UWORD8 maio_bef_sti; BOOL dtx_allowed; T_BCCH_LIST bcch_allocation; UWORD8 ba_id; BOOL pwrc; } T_MPHC_IMMED_ASSIGN_REQ; typedef struct { T_CHANNEL_DESCRIPTION channel_desc_1; UWORD8 channel_mode_1; UWORD8 txpwr; T_MOBILE_ALLOCATION frequency_list; T_STARTING_TIME starting_time; T_CHANNEL_DESCRIPTION channel_desc_2; UWORD8 channel_mode_2; T_MOBILE_ALLOCATION frequency_list_bef_sti; T_CHANNEL_DESCRIPTION channel_desc_1_bef_sti; T_CHANNEL_DESCRIPTION channel_desc_2_bef_sti; UWORD8 cipher_mode; UWORD8 a5_algorithm; T_ENCRYPTION_KEY cipher_key; BOOL dtx_allowed; #if (AMR == 1) T_AMR_CONFIGURATION amr_configuration; #endif } T_MPHC_CHANNEL_ASSIGN_REQ; typedef struct { UWORD8 cipher_mode; UWORD8 a5_algorithm; T_ENCRYPTION_KEY new_ciph_param; } T_MPHC_SET_CIPHERING_REQ; typedef struct { T_CHANNEL_DESCRIPTION channel_desc; T_MOBILE_ALLOCATION frequency_list; T_STARTING_TIME starting_time; } T_MPHC_CHANGE_FREQUENCY; typedef struct { UWORD8 txpwr; UWORD8 rand; UWORD8 channel_request; #if (L1_FF_MULTIBAND == 0) UWORD8 powerclass_band1; UWORD8 powerclass_band2; #endif } T_MPHC_RA_REQ; typedef struct { T_HO_PARAMS handover_command; UWORD32 fn_offset; UWORD32 time_alignmt; T_ENCRYPTION_KEY cipher_key; #if (AMR == 1) T_AMR_CONFIGURATION amr_configuration; #endif // (AMR == 1) #if ((REL99 == 1) && (FF_BHO == 1)) BOOL handover_type; #endif } T_MPHC_ASYNC_HO_REQ; typedef struct { T_HO_PARAMS handover_command; UWORD32 fn_offset; UWORD32 time_alignmt; T_ENCRYPTION_KEY cipher_key; BOOL nci; BOOL timing_advance_valid; UWORD8 timing_advance; #if (AMR == 1) T_AMR_CONFIGURATION amr_configuration; #endif #if ((REL99 == 1) && (FF_BHO == 1)) BOOL handover_type; #endif } T_MPHC_PRE_SYNC_HO_REQ; typedef struct { T_HO_PARAMS handover_command; UWORD32 fn_offset; UWORD32 time_alignmt; T_ENCRYPTION_KEY cipher_key; BOOL nci; UWORD8 real_time_difference; #if ((REL99 == 1) && (FF_BHO == 1)) BOOL handover_type; #endif // #if ((REL99 == 1) && (FF_BHO == 1)) } T_MPHC_PSEUDO_SYNC_HO_REQ; typedef struct { T_HO_PARAMS handover_command; UWORD32 fn_offset; UWORD32 time_alignmt; T_ENCRYPTION_KEY cipher_key; BOOL nci; #if (AMR == 1) T_AMR_CONFIGURATION amr_configuration; #endif #if ((REL99 == 1) && (FF_BHO == 1)) BOOL handover_type; #endif } T_MPHC_SYNC_HO_REQ; typedef struct { UWORD8 cause; #if ((REL99 == 1) && (FF_BHO == 1)) UWORD32 fn_offset; UWORD32 time_alignment; #endif } T_MPHC_HANDOVER_FINISHED; typedef struct { BOOL dtx_used; BOOL meas_valid; WORD16 rxlev_full_acc; UWORD8 rxlev_full_nbr_meas; WORD16 rxlev_sub_acc; UWORD8 rxlev_sub_nbr_meas; UWORD16 rxqual_full_acc_errors; UWORD16 rxqual_full_nbr_bits; UWORD16 rxqual_sub_acc_errors; UWORD16 rxqual_sub_nbr_bits; UWORD8 no_of_ncell_meas; T5_NCELL_MEAS ncell_meas; UWORD8 ba_id; UWORD8 timing_advance; UWORD8 txpwr_used; #if (REL99 == 1) #if FF_EMR WORD16 rxlev_val_acc; UWORD8 rxlev_val_nbr_meas; UWORD32 mean_bep_block_acc; UWORD16 cv_bep_block_acc; UWORD8 mean_bep_block_num; UWORD8 cv_bep_block_num; UWORD8 nbr_rcvd_blocks; #endif #endif // RESERVED: for trace/debug only UWORD8 facch_dl_count; UWORD8 facch_ul_count; #if (FF_REPEATED_DL_FACCH == 1) UWORD8 facch_dl_combined_good_count; /* No of good decoded blocks after combining */ UWORD8 facch_dl_repetition_block_count; /* Total of Dl block count */ #endif } T_MPHC_MEAS_REPORT; typedef T_NEW_BA_LIST T_MPHC_UPDATE_BA_LIST; typedef struct { UWORD8 bs_pa_mfrms; UWORD8 bs_ag_blks_res; BOOL bcch_combined; UWORD8 ccch_group; UWORD8 page_group; UWORD8 page_block_index; UWORD8 page_mode; } T_MPHC_START_CCCH_REQ; typedef struct { UWORD8 sb_flag; //TRUE if SB found and belongs to PLMN, otherwise FALSE UWORD16 radio_freq; // carrier id. UWORD8 bsic; // BSIC. UWORD32 fn_offset; // offset between fn of this NCELL and the SCELL fn. UWORD32 time_alignmt; // time alignment. } T_MPHC_NCELL_SB_READ; typedef T_FULL_LIST_MEAS T_MPHC_RXLEV_REQ; typedef T_FULL_LIST_MEAS T_L1C_VALID_MEAS_INFO; typedef T_MPHC_RXLEV_PERIODIC_IND T_L1C_RXLEV_PERIODIC_DONE; #if (L1_FF_MULTIBAND == 0) typedef struct { UWORD8 radio_band_config; // frequency band configuration: E-GSM, DCS, GSM/DCS, PCS } T_MPHC_INIT_L1_REQ; #else // For Multiband the Init request is just a dummy and init confirm contains info typedef struct { T_L1_MULTIBAND_POWER_CLASS multiband_power_class[NB_MAX_GSM_BANDS]; } T_MPHC_INIT_L1_CON; #endif // L1_FF_MULTIBAND == 0 /****************************************************************/ /* Structure definition for Test <-> L1A messages */ /****************************************************************/ typedef struct { UWORD16 dsp_code_version; UWORD16 dsp_checksum; UWORD16 dsp_patch_version; UWORD16 mcu_tcs_program_release; UWORD16 mcu_tcs_official; UWORD16 mcu_tcs_internal; } T_TST_TEST_HW_CON; typedef struct { UWORD8 type; } T_L1_STATS_REQ; //////////////////// // Trace messages // //////////////////// #if ((TRACE_TYPE == 1) || (TRACE_TYPE == 4) || (TRACE_TYPE == 7)) #if (DSP_DEBUG_TRACE_ENABLE == 1) // DSP DEBUG buffer display typedef struct { UWORD16 size; UWORD32 fn; UWORD16 debug_time; UWORD16 patch_version; UWORD16 trace_level; API buffer[2]; // ANOTHER DEFINITION ??? } T_DSP_DEBUG_INFO; // DSP AMR trace typedef struct { UWORD16 size; UWORD32 fn; API buffer[2]; // ANOTHER DEFINITION ??? } T_DSP_AMR_DEBUG_INFO; #endif typedef struct { UWORD32 trace_config; UWORD32 rtt_cell_enable[8]; UWORD32 rtt_event; } T_TRACE_CONFIG_CHANGE; #if (L1_GPRS) // Packet transfer trace typedef struct { UWORD32 fn; UWORD8 rx_allocation; UWORD8 tx_allocation; BOOL blk_status; UWORD8 dl_cs_type; UWORD8 dl_status[4]; UWORD8 ul_status[8]; } T_CONDENSED_PDTCH_INFO; #endif typedef struct { UWORD8 debug_code; UWORD32 fn; UWORD32 tab[7]; } T_QUICK_TRACE; #endif #if ((TRACE_TYPE == 1) || (TRACE_TYPE == 4) || (TRACE_TYPE == 7)) typedef struct { UWORD8 debug_code; UWORD32 tab[8]; } T_TRACE_INFO; #endif #if (TRACE_TYPE==7) // CPU LOAD // Number of measurements before output to UART #define C_MESURE_DEPTH 13 /* * cpu : hisr cpu load in microseconds * cpu_access : lisr -> hisr begining cpu load in microseconds * fn : Frame number modulo 104 */ typedef struct { UWORD16 cpu; UWORD16 cpu_access; UWORD8 fn; BOOL valid; } T_MESURE; typedef struct { UWORD8 debug_code; T_MESURE tab[C_MESURE_DEPTH]; } T_TRACE_INFO_CPU_LOAD; #endif /****************************************************************/ /* Structure definition for POWER MANAGEMENt. */ /****************************************************************/ typedef struct { UWORD8 sleep_mode; UWORD16 clocks; } T_TST_SLEEP_REQ; // ...................NEW FOR ALR.................... typedef struct { UWORD8 schedule_array_size; T_BCCHS_SCHEDULE schedule_array[10]; } T_MPHC_SCELL_NBCCH_REQ; typedef struct { UWORD8 schedule_array_size; T_BCCHS_SCHEDULE schedule_array[10]; } T_MPHC_SCELL_EBCCH_REQ; typedef struct { UWORD16 radio_freq; UWORD32 fn_offset; UWORD32 time_alignmt; UWORD8 tsc; UWORD16 bcch_blks_req; #if L1_GPRS UWORD8 gprs_priority; #endif } T_MPHC_NCELL_BCCH_REQ; typedef struct { UWORD16 radio_freq; UWORD8 l2_channel; BOOL error_flag; T_RADIO_FRAME l2_frame; UWORD8 tc; WORD8 ccch_lev; UWORD32 fn; // L1S -> L1A data only UWORD8 neigh_id; } T_MPHC_DATA_IND; typedef T_MPHC_DATA_IND T_MPHC_NCELL_BCCH_IND; typedef T_MPHC_DATA_IND T_L1C_BCCHS_INFO; typedef T_MPHC_DATA_IND T_L1C_BCCHN_INFO; typedef struct { UWORD16 radio_freq; UWORD32 fn_offset; UWORD32 time_alignmt; UWORD8 timing_validity; UWORD8 search_mode; } T_MPHC_NETWORK_SYNC_REQ; typedef struct { UWORD16 radio_freq; BOOL sb_flag; UWORD32 fn_offset; UWORD32 time_alignmt; UWORD8 bsic; } T_MPHC_NETWORK_SYNC_IND; typedef struct { UWORD16 radio_freq; UWORD32 fn_offset; UWORD32 time_alignmt; UWORD8 timing_validity; } T_MPHC_NCELL_SYNC_REQ; #if (L1_12NEIGH ==1) typedef struct { UWORD8 eotd; UWORD8 list_size; T_MPHC_NCELL_SYNC_REQ ncell_list[NBR_NEIGHBOURS]; } T_MPHC_NCELL_LIST_SYNC_REQ; #endif typedef struct { UWORD16 radio_freq; BOOL sb_flag; // used to fill "data_valid" field for Cursor UWORD32 fn_offset; UWORD32 time_alignmt; UWORD8 bsic; // L1S -> L1A data only UWORD8 neigh_id; UWORD8 attempt; // RESERVED: for trace/debug and test mode only UWORD32 pm; UWORD32 toa; UWORD32 angle; UWORD32 snr; // EOTD data : L1S -> L1A #if (L1_EOTD==1) UWORD8 eotd_data_valid; // indicates to L3 that it's an EOTD result UWORD8 mode; // indicates to CURSOR that it's Idle(0) or Dedicated (1) WORD16 d_eotd_first; WORD16 d_eotd_max; UWORD32 d_eotd_nrj; WORD16 a_eotd_crosscor[18]; UWORD32 timetag; UWORD32 fn_sb_neigh; // used for Timetag computation UWORD32 fn_in_SB; // sent to CURSOR for SC fn (header=46 ...) // TOA correction for timetag in dedicated mode... WORD32 toa_correction; // for Debug traces ............ UWORD32 delta_fn; WORD32 delta_qbit; #endif } T_MPHC_NCELL_SYNC_IND; typedef T_MPHC_NCELL_SYNC_IND T_L1C_SB_INFO; typedef T_MPHC_NCELL_SYNC_IND T_L1C_SBCONF_INFO; typedef struct { UWORD16 radio_freq; UWORD32 fn_offset; UWORD32 time_alignmt; UWORD8 bsic; } T_MPHC_NEW_SCELL_REQ; typedef struct { BOOL fb_flag; WORD8 ntdma; UWORD8 neigh_id; #if (L1_12NEIGH ==1) // L1S --> L1A data only UWORD8 attempt; #endif // RESERVED: for Trace/Debug and test mode only UWORD32 pm; UWORD32 toa; UWORD32 angle; UWORD32 snr; UWORD16 radio_freq; } T_L1C_FB_INFO; #if ((REL99 == 1) && (FF_BHO == 1)) typedef struct { BOOL fb_flag; BOOL sb_flag; UWORD8 bsic; UWORD32 fn_offset; UWORD32 time_alignmt; UWORD32 pm; UWORD32 toa; UWORD32 angle; UWORD32 snr; } T_L1C_FBSB_INFO; #endif typedef struct { WORD8 radio_freq_array_size; #if (L1_12NEIGH ==1) UWORD16 radio_freq_array[NBR_NEIGHBOURS]; #else UWORD16 radio_freq_array[6]; #endif } T_MPHC_STOP_NCELL_SYNC_REQ; typedef struct { UWORD8 radio_freq_array_size; UWORD16 radio_freq_array[6]; } T_MPHC_STOP_NCELL_BCCH_REQ; typedef struct { T_CHANNEL_DESCRIPTION cbch_desc; T_MOBILE_ALLOCATION cbch_freq_list; } T_MPHC_CONFIG_CBCH_REQ; typedef struct { BOOL extended_cbch; UWORD8 schedule_length; UWORD32 first_block_0; UWORD16 first_block_1; } T_MPHC_CBCH_SCHEDULE_REQ; typedef struct { UWORD8 tb_bitmap; } T_MPHC_CBCH_INFO_REQ; typedef struct { BOOL extended_cbch; UWORD32 first_block_0; UWORD16 first_block_1; } T_MPHC_CBCH_UPDATE_REQ; typedef struct { BOOL normal_cbch; BOOL extended_cbch; } T_MPHC_STOP_CBCH_REQ; // ...................NEW FOR ALR.................... /****************************************************************/ /* Structure definition for L1 configuration. */ /****************************************************************/ typedef struct { UWORD8 std; UWORD8 swap_iq_band1; UWORD8 swap_iq_band2; UWORD8 pwr_mngt; UWORD8 tx_pwr_code; #if IDS UWORD8 ids_enable; #endif T_FACCH_TEST_PARAMS facch_test; UWORD16 dwnld; UWORD8 pwr_mngt_mode_authorized; UWORD32 pwr_mngt_clocks; } T_MMI_L1_CONFIG;