/* * dumpcaps.c - Copyright (C) 2000-2012 Stephane Fillod * This programs dumps the capabilities of a backend rig. * * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * 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, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * */ #include #include #include #include #include "misc.h" #include "sprintflst.h" #include "rigctl_parse.h" #include "../rigs/icom/icom.h" void range_print(FILE *fout, const struct freq_range_list range_list[], int rx); int range_sanity_check(const struct freq_range_list range_list[], int rx); int ts_sanity_check(const struct tuning_step_list tuning_step[]); static void dump_chan_caps(const channel_cap_t *chan, FILE *fout); static int print_ext(RIG *rig, const struct confparams *cfp, rig_ptr_t ptr) { return print_ext_param(cfp, ptr); } /* * the rig may be in rig_init state, but not opened */ int dumpcaps(RIG *rig, FILE *fout) { const struct rig_caps *caps; int status, i; int can_esplit, can_echannel; char freqbuf[20]; int backend_warnings = 0; static char prntbuf[1024]; /* a malloc would be better.. */ char *label1, *label2, *label3, *label4, *label5; char *labelrx1; // , *labelrx2, *labelrx3, *labelrx4, *labelrx5; if (!rig || !rig->caps) { return -RIG_EINVAL; } caps = rig->caps; fprintf(fout, "Caps dump for model: %u\n", caps->rig_model); fprintf(fout, "Model name:\t%s\n", caps->model_name); fprintf(fout, "Mfg name:\t%s\n", caps->mfg_name); fprintf(fout, "Backend version:\t%s\n", caps->version); fprintf(fout, "Backend copyright:\t%s\n", caps->copyright); fprintf(fout, "Backend status:\t%s\n", rig_strstatus(caps->status)); fprintf(fout, "Rig type:\t"); switch (caps->rig_type & RIG_TYPE_MASK) { case RIG_TYPE_TRANSCEIVER: fprintf(fout, "Transceiver\n"); break; case RIG_TYPE_HANDHELD: fprintf(fout, "Handheld\n"); break; case RIG_TYPE_MOBILE: fprintf(fout, "Mobile\n"); break; case RIG_TYPE_RECEIVER: fprintf(fout, "Receiver\n"); break; case RIG_TYPE_PCRECEIVER: fprintf(fout, "PC Receiver\n"); break; case RIG_TYPE_SCANNER: fprintf(fout, "Scanner\n"); break; case RIG_TYPE_TRUNKSCANNER: fprintf(fout, "Trunking scanner\n"); break; case RIG_TYPE_COMPUTER: fprintf(fout, "Computer\n"); break; case RIG_TYPE_TUNER: fprintf(fout, "Tuner\n"); break; case RIG_TYPE_OTHER: fprintf(fout, "Other\n"); break; default: fprintf(fout, "Unknown\n"); backend_warnings++; } fprintf(fout, "PTT type:\t"); switch (caps->ptt_type) { case RIG_PTT_RIG: fprintf(fout, "Rig capable\n"); break; case RIG_PTT_RIG_MICDATA: fprintf(fout, "Rig capable (Mic/Data)\n"); break; case RIG_PTT_PARALLEL: fprintf(fout, "Parallel port (DATA0)\n"); break; case RIG_PTT_SERIAL_RTS: fprintf(fout, "Serial port (CTS/RTS)\n"); break; case RIG_PTT_SERIAL_DTR: fprintf(fout, "Serial port (DTR/DSR)\n"); break; case RIG_PTT_NONE: fprintf(fout, "None\n"); break; default: fprintf(fout, "Unknown\n"); backend_warnings++; } fprintf(fout, "DCD type:\t"); switch (caps->dcd_type) { case RIG_DCD_RIG: fprintf(fout, "Rig capable\n"); break; case RIG_DCD_PARALLEL: fprintf(fout, "Parallel port (/STROBE)\n"); break; case RIG_DCD_SERIAL_CTS: fprintf(fout, "Serial port (CTS/RTS)\n"); break; case RIG_DCD_SERIAL_DSR: fprintf(fout, "Serial port (DTR/DSR)\n"); break; case RIG_DCD_SERIAL_CAR: fprintf(fout, "Serial port (CD)\n"); break; case RIG_DCD_NONE: fprintf(fout, "None\n"); break; default: fprintf(fout, "Unknown\n"); backend_warnings++; } fprintf(fout, "Port type:\t"); switch (caps->port_type) { case RIG_PORT_SERIAL: fprintf(fout, "RS-232\n"); fprintf(fout, "Serial speed: %d..%d bauds, %d%c%d %s\n", caps->serial_rate_min, caps->serial_rate_max, caps->serial_data_bits, caps->serial_parity == RIG_PARITY_NONE ? 'N' : caps->serial_parity == RIG_PARITY_ODD ? 'O' : caps->serial_parity == RIG_PARITY_EVEN ? 'E' : caps->serial_parity == RIG_PARITY_MARK ? 'M' : 'S', caps->serial_stop_bits, caps->serial_handshake == RIG_HANDSHAKE_NONE ? "" : (caps->serial_handshake == RIG_HANDSHAKE_XONXOFF ? "XONXOFF" : "CTS/RTS") ); break; case RIG_PORT_PARALLEL: fprintf(fout, "Parallel\n"); break; case RIG_PORT_DEVICE: fprintf(fout, "Device driver\n"); break; case RIG_PORT_USB: fprintf(fout, "USB\n"); break; case RIG_PORT_NETWORK: fprintf(fout, "Network link\n"); break; case RIG_PORT_UDP_NETWORK: fprintf(fout, "UDP Network link\n"); break; case RIG_PORT_NONE: fprintf(fout, "None\n"); break; default: fprintf(fout, "Unknown\n"); backend_warnings++; } fprintf(fout, "Write delay: %dmS, timeout %dmS, %d retry\n", caps->write_delay, caps->timeout, caps->retry); fprintf(fout, "Post Write delay: %dmS\n", caps->post_write_delay); fprintf(fout, "Has targetable VFO: %s\n", caps->targetable_vfo ? "Y" : "N"); fprintf(fout, "Has async data support: %s\n", caps->async_data_supported ? "Y" : "N"); fprintf(fout, "Announce: 0x%x\n", caps->announces); fprintf(fout, "Max RIT: -%ld.%ldkHz/+%ld.%ldkHz\n", caps->max_rit / 1000, caps->max_rit % 1000, caps->max_rit / 1000, caps->max_rit % 1000); fprintf(fout, "Max XIT: -%ld.%ldkHz/+%ld.%ldkHz\n", caps->max_xit / 1000, caps->max_xit % 1000, caps->max_xit / 1000, caps->max_xit % 1000); fprintf(fout, "Max IF-SHIFT: -%ld.%ldkHz/+%ld.%ldkHz\n", caps->max_ifshift / 1000, caps->max_ifshift % 1000, caps->max_ifshift / 1000, caps->max_ifshift % 1000); fprintf(fout, "Preamp:"); for (i = 0; i < HAMLIB_MAXDBLSTSIZ && caps->preamp[i] != 0; i++) { fprintf(fout, " %ddB", caps->preamp[i]); } if (i == 0) { fprintf(fout, " None"); } fprintf(fout, "\n"); fprintf(fout, "Attenuator:"); for (i = 0; i < HAMLIB_MAXDBLSTSIZ && caps->attenuator[i] != 0; i++) { fprintf(fout, " %ddB", caps->attenuator[i]); } if (i == 0) { fprintf(fout, " None"); } fprintf(fout, "\n"); fprintf(fout, "AGC levels:"); const struct icom_priv_caps *priv_caps = (const struct icom_priv_caps *) rig->caps->priv; if (priv_caps && RIG_BACKEND_NUM(rig->caps->rig_model) == RIG_ICOM && priv_caps->agc_levels_present) { for (i = 0; i <= RIG_AGC_LAST && priv_caps->agc_levels[i].level != RIG_AGC_LAST && priv_caps->agc_levels[i].icom_level >= 0; i++) { fprintf(fout, " %d=%s", priv_caps->agc_levels[i].level, rig_stragclevel(priv_caps->agc_levels[i].level)); } } else { for (i = 0; i < HAMLIB_MAX_AGC_LEVELS && i < caps->agc_level_count; i++) { fprintf(fout, " %d=%s", caps->agc_levels[i], rig_stragclevel(caps->agc_levels[i])); } } if (i == 0) { // Fall back to printing out all levels for backwards-compatibility for (i = RIG_AGC_OFF; i <= RIG_AGC_LAST; i++) { fprintf(fout, " %d=%s", i, rig_stragclevel(i)); } } fprintf(fout, "\n"); fprintf(fout, "CTCSS:"); for (i = 0; caps->ctcss_list && i < 60 && caps->ctcss_list[i] != 0; i++) { fprintf(fout, " %u.%1u", caps->ctcss_list[i] / 10, caps->ctcss_list[i] % 10); } if (i == 0) { fprintf(fout, " None"); } else { fprintf(fout, " Hz, %d tones", i); } fprintf(fout, "\n"); fprintf(fout, "DCS:"); for (i = 0; caps->dcs_list && i < 128 && caps->dcs_list[i] != 0; i++) { fprintf(fout, " %u", caps->dcs_list[i]); } if (i == 0) { fprintf(fout, " None"); } else { fprintf(fout, ", %d codes", i); } fprintf(fout, "\n"); rig_sprintf_func(prntbuf, sizeof(prntbuf), caps->has_get_func); fprintf(fout, "Get functions: %s\n", prntbuf); rig_sprintf_func(prntbuf, sizeof(prntbuf), caps->has_set_func); fprintf(fout, "Set functions: %s\n", prntbuf); fprintf(fout, "Extra functions:\n"); rig_ext_func_foreach(rig, print_ext, fout); rig_sprintf_level_gran(prntbuf, sizeof(prntbuf), caps->has_get_level, caps->level_gran); fprintf(fout, "Get level: %s\n", prntbuf); if ((caps->has_get_level & RIG_LEVEL_RAWSTR) && caps->str_cal.size == 0 && !(caps->has_get_level & RIG_LEVEL_STRENGTH)) { fprintf(fout, "Warning--backend has get RAWSTR, but not calibration data\n"); backend_warnings++; } rig_sprintf_level_gran(prntbuf, sizeof(prntbuf), caps->has_set_level, caps->level_gran); fprintf(fout, "Set level: %s\n", prntbuf); if (caps->has_set_level & RIG_LEVEL_READONLY_LIST) { //fprintf(fout, "Warning--backend can set readonly levels=0x%0llx\n", caps->has_set_level & RIG_LEVEL_READONLY_LIST); fprintf(fout, "Warning--backend can set readonly levels\n"); backend_warnings++; } fprintf(fout, "Extra levels:\n"); rig_ext_level_foreach(rig, print_ext, fout); rig_sprintf_parm_gran(prntbuf, sizeof(prntbuf), caps->has_get_parm, caps->parm_gran); fprintf(fout, "Get parameters: %s\n", prntbuf); rig_sprintf_parm_gran(prntbuf, sizeof(prntbuf), caps->has_set_parm, caps->parm_gran); fprintf(fout, "Set parameters: %s\n", prntbuf); if (caps->has_set_parm & RIG_PARM_READONLY_LIST) { fprintf(fout, "Warning--backend can set readonly parms!\n"); backend_warnings++; } fprintf(fout, "Extra parameters:\n"); rig_ext_parm_foreach(rig, print_ext, fout); if (rig->state.mode_list != 0) { rig_sprintf_mode(prntbuf, sizeof(prntbuf), rig->state.mode_list); } else { strcpy(prntbuf, "None. This backend might be bogus!\n"); backend_warnings++; } fprintf(fout, "Mode list: %s\n", prntbuf); if (rig->state.vfo_list != 0) { rig_sprintf_vfo(prntbuf, sizeof(prntbuf), rig->state.vfo_list); } else { strcpy(prntbuf, "None. This backend might be bogus!\n"); backend_warnings++; } fprintf(fout, "VFO list: %s\n", prntbuf); rig_sprintf_vfop(prntbuf, sizeof(prntbuf), caps->vfo_ops); fprintf(fout, "VFO Ops: %s\n", prntbuf); rig_sprintf_scan(prntbuf, sizeof(prntbuf), caps->scan_ops); fprintf(fout, "Scan Ops: %s\n", prntbuf); fprintf(fout, "Number of banks:\t%d\n", caps->bank_qty); fprintf(fout, "Memory name desc size:\t%d\n", caps->chan_desc_sz); fprintf(fout, "Memories:"); for (i = 0; i < HAMLIB_CHANLSTSIZ && caps->chan_list[i].type; i++) { fprintf(fout, "\n\t%d..%d: \t%s", caps->chan_list[i].startc, caps->chan_list[i].endc, rig_strmtype(caps->chan_list[i].type)); fprintf(fout, "\n\t Mem caps: "); dump_chan_caps(&caps->chan_list[i].mem_caps, fout); } if (i == 0) { fprintf(fout, " None"); } fprintf(fout, "\n"); label1 = caps->tx_range_list1->label; label1 = label1 == NULL ? "TBD" : label1; fprintf(fout, "TX ranges #1 for %s:\n", label1); range_print(fout, caps->tx_range_list1, 0); labelrx1 = caps->rx_range_list1->label; labelrx1 = labelrx1 == NULL ? "TBD" : labelrx1; fprintf(fout, "RX ranges #1 for %s:\n", labelrx1); range_print(fout, caps->rx_range_list1, 1); label2 = caps->rx_range_list2->label; label2 = label2 == NULL ? "TBD" : label2; fprintf(fout, "TX ranges #2 for %s:\n", label2); range_print(fout, caps->tx_range_list2, 0); label2 = caps->rx_range_list2->label; label2 = label2 == NULL ? "TBD" : label2; fprintf(fout, "RX ranges #2 for %s:\n", label2); range_print(fout, caps->rx_range_list2, 1); label3 = caps->rx_range_list3->label; label3 = label3 == NULL ? "TBD" : label3; fprintf(fout, "TX ranges #3 for %s:\n", label3); range_print(fout, caps->tx_range_list3, 0); label3 = caps->rx_range_list3->label; label3 = label3 == NULL ? "TBD" : label3; fprintf(fout, "RX ranges #3 for %s:\n", label3); range_print(fout, caps->rx_range_list3, 1); label4 = caps->rx_range_list4->label; label4 = label4 == NULL ? "TBD" : label4; fprintf(fout, "TX ranges #4 for %s:\n", label4); range_print(fout, caps->tx_range_list5, 0); label4 = caps->rx_range_list4->label; label4 = label4 == NULL ? "TBD" : label4; fprintf(fout, "RX ranges #4 for %s:\n", label4); range_print(fout, caps->rx_range_list5, 1); label5 = caps->rx_range_list5->label; label5 = label5 == NULL ? "TBD" : label5; fprintf(fout, "TX ranges #5 for %s:\n", label5); range_print(fout, caps->tx_range_list5, 0); label5 = caps->rx_range_list5->label; label5 = label5 == NULL ? "TBD" : label5; fprintf(fout, "RX ranges #5 for %s:\n", label5); range_print(fout, caps->rx_range_list5, 1); status = range_sanity_check(caps->tx_range_list1, 0); fprintf(fout, "TX ranges #1 status for %s:\t%s (%d)\n", label1, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->rx_range_list1, 1); fprintf(fout, "RX ranges #1 status for %s:\t%s (%d)\n", labelrx1, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->tx_range_list2, 0); fprintf(fout, "TX ranges #2 status for %s:\t%s (%d)\n", label2, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->rx_range_list2, 1); fprintf(fout, "RX ranges #2 status for %s:\t%s (%d)\n", label2, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->tx_range_list3, 0); fprintf(fout, "TX ranges #3 status for %s:\t%s (%d)\n", label3, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->rx_range_list3, 1); fprintf(fout, "RX ranges #3 status for %s:\t%s (%d)\n", label3, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->tx_range_list4, 0); fprintf(fout, "TX ranges #4 status for %s:\t%s (%d)\n", label4, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->rx_range_list4, 1); fprintf(fout, "RX ranges #4 status for %s:\t%s (%d)\n", label4, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->tx_range_list5, 0); fprintf(fout, "TX ranges #5 status for %s:\t%s (%d)\n", label5, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } status = range_sanity_check(caps->rx_range_list5, 1); fprintf(fout, "RX ranges #5 status for %s:\t%s (%d)\n", label5, status ? "Bad" : "OK", status); if (status) { backend_warnings++; } fprintf(fout, "Tuning steps:"); for (i = 0; i < HAMLIB_TSLSTSIZ && !RIG_IS_TS_END(caps->tuning_steps[i]); i++) { if (caps->tuning_steps[i].ts == RIG_TS_ANY) { strcpy(freqbuf, "ANY"); /* strcpy! Looks safe for now */ } else { sprintf_freq(freqbuf, sizeof(freqbuf), caps->tuning_steps[i].ts); } rig_sprintf_mode(prntbuf, sizeof(prntbuf), caps->tuning_steps[i].modes); fprintf(fout, "\n\t%s: \t%s", freqbuf, prntbuf); } if (i == 0) { fprintf(fout, " None! This backend might be bogus!"); backend_warnings++; } fprintf(fout, "\n"); status = ts_sanity_check(caps->tuning_steps); fprintf(fout, "Tuning steps status:\t%s (%d)\n", status ? "Bad" : "OK", status); if (status) { backend_warnings++; } fprintf(fout, "Filters:"); for (i = 0; i < HAMLIB_FLTLSTSIZ && !RIG_IS_FLT_END(caps->filters[i]); i++) { if (caps->filters[i].width == RIG_FLT_ANY) { strcpy(freqbuf, "ANY"); } else { sprintf_freq(freqbuf, sizeof(freqbuf), caps->filters[i].width); } rig_sprintf_mode(prntbuf, sizeof(prntbuf), caps->filters[i].modes); fprintf(fout, "\n\t%s: \t%s", freqbuf, prntbuf); } if (i == 0) { fprintf(fout, " None. This backend might be bogus!"); backend_warnings++; } fprintf(fout, "\n"); fprintf(fout, "Bandwidths:"); for (i = 1; i < RIG_MODE_TESTS_MAX; i <<= 1) { pbwidth_t pbnorm = rig_passband_normal(rig, i); if (pbnorm == 0) { // continue; } sprintf_freq(freqbuf, sizeof(freqbuf), pbnorm); fprintf(fout, "\n\t%s\tNormal: %s,\t", rig_strrmode(i), freqbuf); sprintf_freq(freqbuf, sizeof(freqbuf), rig_passband_narrow(rig, i)); fprintf(fout, "Narrow: %s,\t", freqbuf); sprintf_freq(freqbuf, sizeof(freqbuf), rig_passband_wide(rig, i)); fprintf(fout, "Wide: %s", freqbuf); } fprintf(fout, "\n"); fprintf(fout, "Spectrum scopes:"); for (i = 0; i < HAMLIB_MAX_SPECTRUM_SCOPES && caps->spectrum_scopes[i].name != NULL; i++) { fprintf(fout, " %d=\"%s\"", caps->spectrum_scopes[i].id, caps->spectrum_scopes[i].name); } if (i == 0) { fprintf(fout, " None"); } fprintf(fout, "\n"); rig_sprintf_spectrum_modes(prntbuf, sizeof(prntbuf), caps->spectrum_modes); fprintf(fout, "Spectrum modes: %s\n", prntbuf); rig_sprintf_spectrum_spans(prntbuf, sizeof(prntbuf), caps->spectrum_spans); fprintf(fout, "Spectrum spans: %s\n", prntbuf); rig_sprintf_spectrum_avg_modes(prntbuf, sizeof(prntbuf), caps->spectrum_avg_modes); fprintf(fout, "Spectrum averaging modes: %s\n", prntbuf); fprintf(fout, "Spectrum attenuator:"); for (i = 0; i < HAMLIB_MAXDBLSTSIZ && caps->spectrum_attenuator[i] != 0; i++) { fprintf(fout, " %ddB", caps->spectrum_attenuator[i]); } if (i == 0) { fprintf(fout, " None"); } fprintf(fout, "\n"); fprintf(fout, "Has priv data:\t%c\n", caps->priv != NULL ? 'Y' : 'N'); /* * Status is either 'Y'es, 'E'mulated, 'N'o * * TODO: keep me up-to-date with API call list! */ fprintf(fout, "Has Init:\t%c\n", caps->rig_init != NULL ? 'Y' : 'N'); fprintf(fout, "Has Cleanup:\t%c\n", caps->rig_cleanup != NULL ? 'Y' : 'N'); fprintf(fout, "Has Open:\t%c\n", caps->rig_open != NULL ? 'Y' : 'N'); fprintf(fout, "Has Close:\t%c\n", caps->rig_close != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Conf:\t%c\n", caps->set_conf != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Conf:\t%c\n", caps->get_conf != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Frequency:\t%c\n", caps->set_freq != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Frequency:\t%c\n", caps->get_freq != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Mode:\t%c\n", caps->set_mode != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Mode:\t%c\n", caps->get_mode != NULL ? 'Y' : 'N'); fprintf(fout, "Can set VFO:\t%c\n", caps->set_vfo != NULL ? 'Y' : 'N'); fprintf(fout, "Can get VFO:\t%c\n", caps->get_vfo != NULL ? 'Y' : 'N'); fprintf(fout, "Can set PTT:\t%c\n", caps->set_ptt != NULL ? 'Y' : 'N'); fprintf(fout, "Can get PTT:\t%c\n", caps->get_ptt != NULL ? 'Y' : 'N'); fprintf(fout, "Can get DCD:\t%c\n", caps->get_dcd != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Repeater Duplex:\t%c\n", caps->set_rptr_shift != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Repeater Duplex:\t%c\n", caps->get_rptr_shift != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Repeater Offset:\t%c\n", caps->set_rptr_offs != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Repeater Offset:\t%c\n", caps->get_rptr_offs != NULL ? 'Y' : 'N'); can_esplit = caps->set_split_vfo && (caps->set_vfo || (rig_has_vfo_op(rig, RIG_OP_TOGGLE) && caps->vfo_op)); fprintf(fout, "Can set Split Freq:\t%c\n", caps->set_split_freq != NULL ? 'Y' : (can_esplit && caps->set_freq ? 'E' : 'N')); fprintf(fout, "Can get Split Freq:\t%c\n", caps->get_split_freq != NULL ? 'Y' : (can_esplit && caps->get_freq ? 'E' : 'N')); fprintf(fout, "Can set Split Mode:\t%c\n", caps->set_split_mode != NULL ? 'Y' : (can_esplit && caps->set_mode ? 'E' : 'N')); fprintf(fout, "Can get Split Mode:\t%c\n", caps->get_split_mode != NULL ? 'Y' : (can_esplit && caps->get_mode ? 'E' : 'N')); fprintf(fout, "Can set Split VFO:\t%c\n", caps->set_split_vfo != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Split VFO:\t%c\n", caps->get_split_vfo != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Tuning Step:\t%c\n", caps->set_ts != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Tuning Step:\t%c\n", caps->get_ts != NULL ? 'Y' : 'N'); fprintf(fout, "Can set RIT:\t%c\n", caps->set_rit != NULL ? 'Y' : 'N'); fprintf(fout, "Can get RIT:\t%c\n", caps->get_rit != NULL ? 'Y' : 'N'); fprintf(fout, "Can set XIT:\t%c\n", caps->set_xit != NULL ? 'Y' : 'N'); fprintf(fout, "Can get XIT:\t%c\n", caps->get_xit != NULL ? 'Y' : 'N'); fprintf(fout, "Can set CTCSS:\t%c\n", caps->set_ctcss_tone != NULL ? 'Y' : 'N'); fprintf(fout, "Can get CTCSS:\t%c\n", caps->get_ctcss_tone != NULL ? 'Y' : 'N'); fprintf(fout, "Can set DCS:\t%c\n", caps->set_dcs_code != NULL ? 'Y' : 'N'); fprintf(fout, "Can get DCS:\t%c\n", caps->get_dcs_code != NULL ? 'Y' : 'N'); fprintf(fout, "Can set CTCSS Squelch:\t%c\n", caps->set_ctcss_sql != NULL ? 'Y' : 'N'); fprintf(fout, "Can get CTCSS Squelch:\t%c\n", caps->get_ctcss_sql != NULL ? 'Y' : 'N'); fprintf(fout, "Can set DCS Squelch:\t%c\n", caps->set_dcs_sql != NULL ? 'Y' : 'N'); fprintf(fout, "Can get DCS Squelch:\t%c\n", caps->get_dcs_sql != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Power Stat:\t%c\n", caps->set_powerstat != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Power Stat:\t%c\n", caps->get_powerstat != NULL ? 'Y' : 'N'); fprintf(fout, "Can Reset:\t%c\n", caps->reset != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Ant:\t%c\n", caps->get_ant != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Ant:\t%c\n", caps->set_ant != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Transceive:\t%c\n", caps->set_trn != NULL ? 'Y' : caps->transceive == RIG_TRN_RIG ? 'E' : 'N'); fprintf(fout, "Can get Transceive:\t%c\n", caps->get_trn != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Func:\t%c\n", caps->set_func != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Func:\t%c\n", caps->get_func != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Level:\t%c\n", caps->set_level != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Level:\t%c\n", caps->get_level != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Param:\t%c\n", caps->set_parm != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Param:\t%c\n", caps->get_parm != NULL ? 'Y' : 'N'); fprintf(fout, "Can send DTMF:\t%c\n", caps->send_dtmf != NULL ? 'Y' : 'N'); fprintf(fout, "Can recv DTMF:\t%c\n", caps->recv_dtmf != NULL ? 'Y' : 'N'); fprintf(fout, "Can send Morse:\t%c\n", caps->send_morse != NULL ? 'Y' : 'N'); fprintf(fout, "Can send Voice:\t%c\n", caps->send_voice_mem != NULL ? 'Y' : 'N'); fprintf(fout, "Can decode Events:\t%c\n", caps->decode_event != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Bank:\t%c\n", caps->set_bank != NULL ? 'Y' : 'N'); fprintf(fout, "Can set Mem:\t%c\n", caps->set_mem != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Mem:\t%c\n", caps->get_mem != NULL ? 'Y' : 'N'); can_echannel = caps->set_mem && ((caps->set_vfo && ((rig->state.vfo_list & RIG_VFO_MEM) == RIG_VFO_MEM)) || (caps->vfo_op && rig_has_vfo_op(rig, RIG_OP_TO_VFO | RIG_OP_FROM_VFO))); fprintf(fout, "Can set Channel:\t%c\n", caps->set_channel != NULL ? 'Y' : (can_echannel ? 'E' : 'N')); fprintf(fout, "Can get Channel:\t%c\n", caps->get_channel != NULL ? 'Y' : (can_echannel ? 'E' : 'N')); fprintf(fout, "Can ctl Mem/VFO:\t%c\n", caps->vfo_op != NULL ? 'Y' : 'N'); fprintf(fout, "Can Scan:\t%c\n", caps->scan != NULL ? 'Y' : 'N'); fprintf(fout, "Can get Info:\t%c\n", caps->get_info != NULL ? 'Y' : 'N'); fprintf(fout, "Can get power2mW:\t%c\n", caps->power2mW != NULL ? 'Y' : 'N'); fprintf(fout, "Can get mW2power:\t%c\n", caps->mW2power != NULL ? 'Y' : 'N'); fprintf(fout, "\nOverall backend warnings: %d\n", backend_warnings); return backend_warnings; } void range_print(FILE *fout, const struct freq_range_list range_list[], int rx) { int i; char prntbuf[1024]; /* a malloc would be better.. */ for (i = 0; i < HAMLIB_FRQRANGESIZ; i++) { if (range_list[i].startf == 0 && range_list[i].endf == 0) { break; } fprintf(fout, "\t%.0f Hz - %.0f Hz\n", range_list[i].startf, range_list[i].endf); fprintf(fout, "\t\tVFO list: "); rig_sprintf_vfo(prntbuf, sizeof(prntbuf), range_list[i].vfo); fprintf(fout, "%s", prntbuf); fprintf(fout, "\n"); fprintf(fout, "\t\tMode list: "); rig_sprintf_mode(prntbuf, sizeof(prntbuf), range_list[i].modes); fprintf(fout, "%s", prntbuf); fprintf(fout, "\n"); fprintf(fout, "\t\tAntenna list: "); rig_sprintf_ant(prntbuf, sizeof(prntbuf), range_list[i].ant); fprintf(fout, "%s", prntbuf); fprintf(fout, "\n"); if (!rx) { char *label_lo = "W"; char *label_hi = "W"; double low = range_list[i].low_power / 1000.0f; double hi = range_list[i].high_power / 1000.0f; if (low < 0) { label_lo = "mW"; low *= 1000; } if (low < 0) { label_lo = "uW"; low *= 1000; } if (hi < 0) { label_hi = "mW"; hi *= 1000; } if (hi < 0) { label_hi = "uW"; hi *= 1000; } fprintf(fout, "\t\tLow power: %g %s, High power: %g %s\n", low, label_lo, hi, label_hi); } } } /* * check for: * - start_freq < end_freq return_code = -1 * - modes are not 0 return_code = -2 * - if(rx), low_power, high_power set to -1 return_code = -3 * else, power is > 0 * - array is ended by a {0,0,0,0,0} element (before boundary) rc = -4 * - ranges with same modes do not overlap rc = -5 * ->fprintf(stderr,)! * * TODO: array is sorted in ascending freq order */ int range_sanity_check(const struct freq_range_list range_list[], int rx) { int i; for (i = 0; i < HAMLIB_FRQRANGESIZ; i++) { if (range_list[i].startf == 0 && range_list[i].endf == 0) { break; } if (range_list[i].startf > range_list[i].endf) { return -1; } if (range_list[i].modes == 0) { return -2; } if (rx) { if (range_list[i].low_power > 0 && range_list[i].high_power > 0) { return -3; } } else { if (!(range_list[i].low_power > 0 && range_list[i].high_power > 0)) { return -3; } if (range_list[i].low_power > range_list[i].high_power) { return -3; } } } if (i == HAMLIB_FRQRANGESIZ) { return -4; } return 0; } /* * check for: * - steps sorted in ascending order return_code=-1 * - modes are not 0 return_code=-2 * - array is ended by a {0,0,0,0,0} element (before boundary) rc=-4 * * TODO: array is sorted in ascending freq order */ int ts_sanity_check(const struct tuning_step_list tuning_step[]) { int i; shortfreq_t last_ts; rmode_t last_modes; last_ts = 0; last_modes = RIG_MODE_NONE; for (i = 0; i < HAMLIB_TSLSTSIZ; i++) { if (RIG_IS_TS_END(tuning_step[i])) { break; } if (tuning_step[i].ts != RIG_TS_ANY && tuning_step[i].ts < last_ts && last_modes == tuning_step[i].modes) { return -1; } if (tuning_step[i].modes == 0) { return -2; } last_ts = tuning_step[i].ts; last_modes = tuning_step[i].modes; } if (i == HAMLIB_TSLSTSIZ) { return -4; } return 0; } static void dump_chan_caps(const channel_cap_t *chan, FILE *fout) { if (chan->bank_num) { fprintf(fout, "BANK "); } if (chan->ant) { fprintf(fout, "ANT "); } if (chan->freq) { fprintf(fout, "FREQ "); } if (chan->mode) { fprintf(fout, "MODE "); } if (chan->width) { fprintf(fout, "WIDTH "); } if (chan->tx_freq) { fprintf(fout, "TXFREQ "); } if (chan->tx_mode) { fprintf(fout, "TXMODE "); } if (chan->tx_width) { fprintf(fout, "TXWIDTH "); } if (chan->split) { fprintf(fout, "SPLIT "); } if (chan->rptr_shift) { fprintf(fout, "RPTRSHIFT "); } if (chan->rptr_offs) { fprintf(fout, "RPTROFS "); } if (chan->tuning_step) { fprintf(fout, "TS "); } if (chan->rit) { fprintf(fout, "RIT "); } if (chan->xit) { fprintf(fout, "XIT "); } if (chan->funcs) { fprintf(fout, "FUNC "); /* TODO: iterate over the list */ } if (chan->levels) { fprintf(fout, "LEVEL "); /* TODO: iterate over the list */ } if (chan->ctcss_tone) { fprintf(fout, "TONE "); } if (chan->ctcss_sql) { fprintf(fout, "CTCSS "); } if (chan->dcs_code) { fprintf(fout, "DCSCODE "); } if (chan->dcs_sql) { fprintf(fout, "DCSSQL "); } if (chan->scan_group) { fprintf(fout, "SCANGRP "); } if (chan->flags) { fprintf(fout, "FLAG "); /* TODO: iterate over the RIG_CHFLAG's */ } if (chan->channel_desc) { fprintf(fout, "NAME "); } if (chan->ext_levels) { fprintf(fout, "EXTLVL "); } } int dumpconf(RIG *rig, FILE *fout) { fprintf(fout, "model: %s\n", rig->caps->model_name); rig_token_foreach(rig, print_conf_list, (rig_ptr_t)rig); return 0; }