FreeCalypso > hg > freecalypso-tools
view rvinterf/tmsh/l1cmd.c @ 505:7bf0d909c87e
fc-loadtool flash ID check: change of reset after the check logic
This change only affects those flash configurations that have ID checks
enabled. The logic for resetting the flash after the ID check has been
changed as follows:
1) If the check fails, we return without attempting to reset the flash.
2) If the check is successful, we reset the flash using the configured
method (could be AMD or Intel or Intel W30) instead of always doing an
AMD flash reset as the original code did.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Mon, 27 May 2019 19:58:01 +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); }