FreeCalypso > hg > freecalypso-tools
view rvinterf/tmsh/l1cmd.c @ 816:b3724fe6c581
fc-tmsh bsim commands implemented
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Fri, 14 May 2021 17:16:43 +0000 |
| parents | 92c982f67247 |
| children |
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/* * In this module we are going to implement commands which send * TM3 command packets to the L1TM firmware component: RF calibration * and test modes. */ #include <sys/types.h> #include <ctype.h> #include <stdio.h> #include <string.h> #include <strings.h> #include <stdlib.h> #include "pktmux.h" #include "limits.h" #include "localtypes.h" #include "tm3.h" #include "l1tm.h" #include "exitcodes.h" cmd_tminit(argc, argv) char **argv; { u_char cmdpkt[3]; cmdpkt[1] = TM_INIT; send_etm_cmd(cmdpkt, 1); return(0); } cmd_tms(argc, argv) char **argv; { u16 arg; u_char cmdpkt[5]; arg = strtoul(argv[1], 0, 0); cmdpkt[1] = TM_MODE_SET; cmdpkt[2] = arg; cmdpkt[3] = arg >> 8; send_etm_cmd(cmdpkt, 3); return(0); } cmd_tm3ver(argc, argv) char **argv; { u16 arg; u_char cmdpkt[5]; arg = strtoul(argv[1], 0, 16); cmdpkt[1] = VERSION_GET; cmdpkt[2] = arg; cmdpkt[3] = arg >> 8; send_etm_cmd(cmdpkt, 3); return(0); } static is_num_string(argstr) char *argstr; { char *cp = argstr; if (!isdigit(*cp++)) return(0); while (*cp) { if (!isdigit(*cp++)) return(0); } return(1); } struct kwtab { char *kw; int val; }; static keyword_or_num(argstr, kwtab, valp) char *argstr; struct kwtab *kwtab; u16 *valp; { struct kwtab *tp; if (is_num_string(argstr)) { *valp = atoi(argstr); return(0); } for (tp = kwtab; tp->kw; tp++) { if (!strcmp(tp->kw, argstr)) { *valp = tp->val; return(0); } } printf("error: non-numeric argument not understood\n"); return(ERROR_USAGE); } static struct kwtab rfe_arg[] = { {"stop-all", STOP_ALL}, {"rx-tch", RX_TCH}, {"tx-tch", TX_TCH}, {"rx-tx-tch", RX_TX_TCH}, {"rx-tx-pdtch", RX_TX_PDTCH}, {"rx-tch-cont", RX_TCH_CONT}, {"tx-tch-cont", TX_TCH_CONT}, {"bcch-loop", BCCH_LOOP}, {"sb-loop", SB_LOOP}, {"fb1-loop", FB1_LOOP}, {"fb0-loop", FB0_LOOP}, {"single-pm", SINGLE_PM}, {"rx-tx-pdtch-mon", RX_TX_PDTCH_MON}, {"rx-tx-mon-tch", RX_TX_MON_TCH}, {"rx-tx-mon", RX_TX_MON}, {0, 0} }; cmd_rfe(argc, argv) char **argv; { u16 arg; u_char cmdpkt[5]; if (keyword_or_num(argv[1], rfe_arg, &arg)) return(ERROR_USAGE); cmdpkt[1] = RF_ENABLE; cmdpkt[2] = arg; cmdpkt[3] = arg >> 8; send_etm_cmd(cmdpkt, 3); return(0); } static struct kwtab stats_config_arg[] = { {"loops", LOOPS}, {"auto-result-loops", AUTO_RESULT_LOOPS}, {"auto-reset-loops", AUTO_RESET_LOOPS}, {"stat-gprs-slots", STAT_GPRS_SLOTS}, {"stat-type", STAT_TYPE}, {"stat-bitmask", STAT_BITMASK}, {0, 0} }; cmd_scw(argc, argv) char **argv; { u16 index, value; u_char cmdpkt[7]; if (keyword_or_num(argv[1], stats_config_arg, &index)) return(ERROR_USAGE); value = strtoul(argv[2], 0, 0); cmdpkt[1] = STATS_CONFIG_WRITE; cmdpkt[2] = index; cmdpkt[3] = index >> 8; cmdpkt[4] = value; cmdpkt[5] = value >> 8; send_etm_cmd(cmdpkt, 5); return(0); } cmd_scr(argc, argv) char **argv; { u16 index; u_char cmdpkt[5]; if (keyword_or_num(argv[1], stats_config_arg, &index)) return(ERROR_USAGE); cmdpkt[1] = STATS_CONFIG_READ; cmdpkt[2] = index; cmdpkt[3] = index >> 8; send_etm_cmd(cmdpkt, 3); return(0); } static struct kwtab stats_read_arg[] = { {"accum", ACCUMULATED_RX_STATS}, {"most-recent", MOST_RECENT_RX_STATS}, {0, 0} }; cmd_sr(argc, argv) char **argv; { u16 type, bitmask; u_char cmdpkt[7]; if (keyword_or_num(argv[1], stats_read_arg, &type)) return(ERROR_USAGE); bitmask = strtoul(argv[2], 0, 16); cmdpkt[1] = STATS_READ; cmdpkt[2] = type; cmdpkt[3] = type >> 8; cmdpkt[4] = bitmask; cmdpkt[5] = bitmask >> 8; send_etm_cmd(cmdpkt, 5); return(0); } static struct kwtab rf_param_arg[] = { {"bcch-arfcn", BCCH_ARFCN}, {"tch-arfcn", TCH_ARFCN}, {"mon-arfcn", MON_ARFCN}, {"pdtch-arfcn", PDTCH_ARFCN}, {"std-band", STD_BAND_FLAG}, {"afc-enable", AFC_ENA_FLAG}, {"afc-dac-val", AFC_DAC_VALUE}, {"init-afc-dac", INITIAL_AFC_DAC}, {"multislot-class", MULTISLOT_CLASS}, {0, 0} }; cmd_rfpw2(argc, argv) char **argv; { u16 index, value; u_char cmdpkt[7]; if (keyword_or_num(argv[1], rf_param_arg, &index)) return(ERROR_USAGE); value = strtol(argv[2], 0, 0); cmdpkt[1] = RF_PARAM_WRITE; cmdpkt[2] = index; cmdpkt[3] = index >> 8; cmdpkt[4] = value; cmdpkt[5] = value >> 8; send_etm_cmd(cmdpkt, 5); return(0); } cmd_rfpw3(argc, argv) char **argv; { u16 index; u8 val1, val2; u_char cmdpkt[7]; if (keyword_or_num(argv[1], rf_param_arg, &index)) return(ERROR_USAGE); val1 = strtoul(argv[2], 0, 0); val2 = strtoul(argv[3], 0, 0); cmdpkt[1] = RF_PARAM_WRITE; cmdpkt[2] = index; cmdpkt[3] = index >> 8; cmdpkt[4] = val1; cmdpkt[5] = val2; send_etm_cmd(cmdpkt, 5); return(0); } cmd_rfpw(argc, argv) char **argv; { switch (argc) { case 3: return cmd_rfpw2(argc, argv); case 4: return cmd_rfpw3(argc, argv); default: fprintf(stderr, "BUG: wrong argc in cmd_rfpw()\n"); return(ERROR_BUG); } } cmd_rfpr(argc, argv) char **argv; { u16 index; u_char cmdpkt[5]; if (keyword_or_num(argv[1], rf_param_arg, &index)) return(ERROR_USAGE); cmdpkt[1] = RF_PARAM_READ; cmdpkt[2] = index; cmdpkt[3] = index >> 8; send_etm_cmd(cmdpkt, 3); return(0); } static struct kwtab rf_table_arg[] = { {"rx-agc-table", RX_AGC_TABLE}, {"afcparams", AFC_PARAMS}, {"rx-agc-global-params", RX_AGC_GLOBAL_PARAMS}, {"rx-il2agc-max", RX_IL_2_AGC_MAX}, {"rx-il2agc-pwr", RX_IL_2_AGC_PWR}, {"rx-il2agc-av", RX_IL_2_AGC_AV}, {"tx-levels", TX_LEVELS}, {"tx-calchan", TX_CAL_CHAN}, {"tx-caltemp", TX_CAL_TEMP}, {"tx-cal-extreme", TX_CAL_EXTREME}, {"rx-calchan", RX_CAL_CHAN}, {"rx-caltemp", RX_CAL_TEMP}, {"rx-cal-level", RX_CAL_LEVEL}, {"rx-agcparams", RX_AGC_PARAMS}, {"rx-agcparams-pcs", RX_AGC_PARAMS_PCS}, {"tx-data-buffer", TX_DATA_BUFFER}, {"rlc-tx-buffer-cs1", RLC_TX_BUFFER_CS1}, {"rlc-tx-buffer-cs2", RLC_TX_BUFFER_CS2}, {"rlc-tx-buffer-cs3", RLC_TX_BUFFER_CS3}, {"rlc-tx-buffer-cs4", RLC_TX_BUFFER_CS4}, {0, 0} }; cmd_rftw(argc, argv) char **argv; { u16 index; u_char cmdpkt[MAX_RF_TABLE_SIZE + 4]; int rc; char *format; unsigned size; if (keyword_or_num(argv[1], rf_table_arg, &index)) return(ERROR_USAGE); cmdpkt[1] = RF_TABLE_WRITE; cmdpkt[2] = index; rc = read_rf_table_ext(argv[2], cmdpkt + 3, 0, &format, &size); if (rc) return(rc); if (argc > 3) { if (strcmp(argv[3], "force")) { printf("error: unexpected 3rd argument\n"); return(ERROR_USAGE); } } else { rc = rftw_index_format_check(index, format); if (rc) return(rc); } send_etm_cmd(cmdpkt, size + 2); return(0); } cmd_rftr(argc, argv) char **argv; { u16 index; u_char cmdpkt[4]; if (keyword_or_num(argv[1], rf_table_arg, &index)) return(ERROR_USAGE); cmdpkt[1] = RF_TABLE_READ; cmdpkt[2] = index; send_etm_cmd(cmdpkt, 2); return(0); } static struct kwtab rx_param_arg[] = { {"agc-gain", RX_AGC_GAIN}, {"timeslot", RX_TIMESLOT}, {"agc-enable", RX_AGC_ENA_FLAG}, {"pm-enable", RX_PM_ENABLE}, {"front-delay", RX_FRONT_DELAY}, {"flags-cal", RX_FLAGS_CAL}, {"flags-platform", RX_FLAGS_PLATFORM}, {"flags-iq-swap", RX_FLAGS_IQ_SWAP}, {"flags-all", RX_FLAGS_ALL}, {"gprs-slots", RX_GPRS_SLOTS}, {"gprs-coding", RX_GPRS_CODING}, {0, 0} }; cmd_rxpw(argc, argv) char **argv; { u16 index, value; u_char cmdpkt[7]; if (keyword_or_num(argv[1], rx_param_arg, &index)) return(ERROR_USAGE); value = strtol(argv[2], 0, 0); cmdpkt[1] = RX_PARAM_WRITE; cmdpkt[2] = index; cmdpkt[3] = index >> 8; cmdpkt[4] = value; cmdpkt[5] = value >> 8; send_etm_cmd(cmdpkt, 5); return(0); } cmd_rxpr(argc, argv) char **argv; { u16 index; u_char cmdpkt[5]; if (keyword_or_num(argv[1], rx_param_arg, &index)) return(ERROR_USAGE); cmdpkt[1] = RX_PARAM_READ; cmdpkt[2] = index; cmdpkt[3] = index >> 8; send_etm_cmd(cmdpkt, 3); return(0); } static struct kwtab tx_param_arg[] = { {"pwr-level", TX_PWR_LEVEL}, {"apc-dac", TX_APC_DAC}, {"ramp-template", TX_RAMP_TEMPLATE}, {"chan-cal-table", TX_CHAN_CAL_TABLE}, {"burst-type", TX_BURST_TYPE}, {"burst-data", TX_BURST_DATA}, {"timing-advance", TX_TIMING_ADVANCE}, {"training-seq", TX_TRAINING_SEQ}, {"pwr-skip", TX_PWR_SKIP}, {"flags-cal", TX_FLAGS_CAL}, {"flags-platform", TX_FLAGS_PLATFORM}, {"flags-iq-swap", TX_FLAGS_IQ_SWAP}, {"flags-all", TX_FLAGS_ALL}, {"gprs-power0", TX_GPRS_POWER0}, {"gprs-power1", TX_GPRS_POWER1}, {"gprs-power2", TX_GPRS_POWER2}, {"gprs-power3", TX_GPRS_POWER3}, {"gprs-power4", TX_GPRS_POWER4}, {"gprs-power5", TX_GPRS_POWER5}, {"gprs-power6", TX_GPRS_POWER6}, {"gprs-power7", TX_GPRS_POWER7}, {"gprs-slots", TX_GPRS_SLOTS}, {"gprs-coding", TX_GPRS_CODING}, {0, 0} }; cmd_txpw(argc, argv) char **argv; { u16 index, value; u_char cmdpkt[7]; if (keyword_or_num(argv[1], tx_param_arg, &index)) return(ERROR_USAGE); value = strtol(argv[2], 0, 0); cmdpkt[1] = TX_PARAM_WRITE; cmdpkt[2] = index; cmdpkt[3] = index >> 8; cmdpkt[4] = value; cmdpkt[5] = value >> 8; send_etm_cmd(cmdpkt, 5); return(0); } cmd_txpr(argc, argv) char **argv; { u16 index; u_char cmdpkt[5]; if (keyword_or_num(argv[1], tx_param_arg, &index)) return(ERROR_USAGE); cmdpkt[1] = TX_PARAM_READ; cmdpkt[2] = index; cmdpkt[3] = index >> 8; send_etm_cmd(cmdpkt, 3); return(0); } cmd_ttw(argc, argv) char **argv; { unsigned index; u_char cmdpkt[36]; int rc; index = strtoul(argv[1], 0, 0); if (index >= 16) { printf("error: index out of range\n"); return(ERROR_USAGE); } cmdpkt[1] = TX_TEMPLATE_WRITE; cmdpkt[2] = index; rc = read_tx_ramp_template(argv[2], cmdpkt + 3); if (rc) return(rc); send_etm_cmd(cmdpkt, 34); return(0); } cmd_ttr(argc, argv) char **argv; { unsigned index; u_char cmdpkt[4]; index = strtoul(argv[1], 0, 0); if (index >= 16) { printf("error: index out of range\n"); return(ERROR_USAGE); } cmdpkt[1] = TX_TEMPLATE_READ; cmdpkt[2] = index; send_etm_cmd(cmdpkt, 2); return(0); } static struct kwtab misc_param_arg[] = { {"adc-interval", ADC_INTERVAL}, {"adc-enable", ADC_ENA_FLAG}, {"converted-adc0", CONVERTED_ADC0}, {"converted-adc1", CONVERTED_ADC1}, {"converted-adc2", CONVERTED_ADC2}, {"converted-adc3", CONVERTED_ADC3}, {"converted-adc4", CONVERTED_ADC4}, {"converted-adc5", CONVERTED_ADC5}, {"converted-adc6", CONVERTED_ADC6}, {"converted-adc7", CONVERTED_ADC7}, {"converted-adc8", CONVERTED_ADC8}, {"raw-adc0", RAW_ADC0}, {"raw-adc1", RAW_ADC1}, {"raw-adc2", RAW_ADC2}, {"raw-adc3", RAW_ADC3}, {"raw-adc4", RAW_ADC4}, {"raw-adc5", RAW_ADC5}, {"raw-adc6", RAW_ADC6}, {"raw-adc7", RAW_ADC7}, {"raw-adc8", RAW_ADC8}, {"adc0-coeff-a", ADC0_COEFF_A}, {"adc1-coeff-a", ADC1_COEFF_A}, {"adc2-coeff-a", ADC2_COEFF_A}, {"adc3-coeff-a", ADC3_COEFF_A}, {"adc4-coeff-a", ADC4_COEFF_A}, {"adc5-coeff-a", ADC5_COEFF_A}, {"adc6-coeff-a", ADC6_COEFF_A}, {"adc7-coeff-a", ADC7_COEFF_A}, {"adc8-coeff-a", ADC8_COEFF_A}, {"adc0-coeff-b", ADC0_COEFF_B}, {"adc1-coeff-b", ADC1_COEFF_B}, {"adc2-coeff-b", ADC2_COEFF_B}, {"adc3-coeff-b", ADC3_COEFF_B}, {"adc4-coeff-b", ADC4_COEFF_B}, {"adc5-coeff-b", ADC5_COEFF_B}, {"adc6-coeff-b", ADC6_COEFF_B}, {"adc7-coeff-b", ADC7_COEFF_B}, {"adc8-coeff-b", ADC8_COEFF_B}, {"sleep-mode", SLEEP_MODE}, {"current-tm-mode", CURRENT_TM_MODE}, {0, 0} }; cmd_mpw(argc, argv) char **argv; { u16 index, value; u_char cmdpkt[7]; if (keyword_or_num(argv[1], misc_param_arg, &index)) return(ERROR_USAGE); value = strtol(argv[2], 0, 0); cmdpkt[1] = MISC_PARAM_WRITE; cmdpkt[2] = index; cmdpkt[3] = index >> 8; cmdpkt[4] = value; cmdpkt[5] = value >> 8; send_etm_cmd(cmdpkt, 5); return(0); } cmd_mpr(argc, argv) char **argv; { u16 index; u_char cmdpkt[5]; if (keyword_or_num(argv[1], misc_param_arg, &index)) return(ERROR_USAGE); cmdpkt[1] = MISC_PARAM_READ; cmdpkt[2] = index; cmdpkt[3] = index >> 8; send_etm_cmd(cmdpkt, 3); return(0); } static struct kwtab me_arg[] = { {"mkdirs", CFG_WRITE_MKDIRS}, {"save-rf-cal", CFG_WRITE_RF_CAL}, {"save-rf-cfg", CFG_WRITE_RF_CFG}, {"save-tx-cal", CFG_WRITE_TX_CAL}, {"save-tx-cfg", CFG_WRITE_TX_CFG}, {"save-rx-cal", CFG_WRITE_RX_CAL}, {"save-rx-cfg", CFG_WRITE_RX_CFG}, {"save-sys-cal", CFG_WRITE_SYS_CAL}, {"save-sys-cfg", CFG_WRITE_SYS_CFG}, {0, 0} }; cmd_me(argc, argv) char **argv; { u16 arg; u_char cmdpkt[5]; if (keyword_or_num(argv[1], me_arg, &arg)) return(ERROR_USAGE); cmdpkt[1] = MISC_ENABLE; cmdpkt[2] = arg; cmdpkt[3] = arg >> 8; send_etm_cmd(cmdpkt, 3); return(0); }