mirror of
https://github.com/portapack-mayhem/mayhem-firmware.git
synced 2024-12-23 16:37:43 +00:00
5cd9c377d2
* added auto record checbox and functions (audio and raw) * Changed baseband compile option from -O3 to -O2. Trying lower gave unexpeted and crashing results. * added 650k SPEC bw * fix hang if wait is -100 * fixing no SPEC support in scanner
470 lines
16 KiB
C++
470 lines
16 KiB
C++
/*
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* Copyright (C) 2014 Jared Boone, ShareBrained Technology, Inc.
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* Copyright (C) 2016 Furrtek
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* Copyright (C) 2023 gullradriel, Nilorea Studio Inc.
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*
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* This file is part of PortaPack.
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2, or (at your option)
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* any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; see the file COPYING. If not, write to
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* the Free Software Foundation, Inc., 51 Franklin Street,
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* Boston, MA 02110-1301, USA.
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*/
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#include "freqman.hpp"
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#include <algorithm>
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using option_t = std::pair<std::string, int32_t>;
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using options_t = std::vector<option_t>;
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options_t freqman_entry_modulations = {
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{"AM", 0},
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{"NFM", 1},
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{"WFM", 2},
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{"SPEC", 3}};
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options_t freqman_entry_bandwidths[4] = {
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{// AM
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{"DSB 9k", 0},
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{"DSB 6k", 1},
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{"USB+3k", 2},
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{"LSB-3k", 3},
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{"CW", 4}},
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{// NFM
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{"8k5", 0},
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{"11k", 1},
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{"16k", 2}},
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{
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// WFM
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{"40k", 2},
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{"180k", 1},
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{"200k", 0},
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},
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{
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// SPEC
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{"8k5", 8500},
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{"11k", 11000},
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{"16k", 16000},
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{"25k", 25000},
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{"50k", 50000},
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{"100k", 100000},
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{"250k", 250000},
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{"500k", 500000}, /* Previous Limit bandwith Option with perfect micro SD write .C16 format operaton.*/
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{"600k", 600000}, /* That extended option is still possible to record with FW version Mayhem v1.41 (< 2,5MB/sec) */
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{"650k", 650000},
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{"750k", 750000}, /* From this BW onwards, the LCD is ok, but the recorded file is decimated, (not real file size) */
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{"1100k", 1100000},
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{"1750k", 1750000},
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{"2000k", 2000000},
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{"2500k", 2500000},
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{"2750k", 2750000}, // That is our max Capture option, to keep using later / 8 decimation (22Mhz sampling ADC)
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}};
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options_t freqman_entry_steps = {
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{"0.1kHz ", 100},
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{"1kHz ", 1000},
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{"5kHz (SA AM)", 5000},
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{"6.25kHz(NFM)", 6250},
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{"8.33kHz(AIR)", 8330},
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{"9kHz (EU AM)", 9000},
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{"10kHz(US AM)", 10000},
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{"12.5kHz(NFM)", 12500},
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{"15kHz (HFM)", 15000},
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{"25kHz (N1)", 25000},
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{"30kHz (OIRT)", 30000},
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{"50kHz (FM1)", 50000},
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{"100kHz (FM2)", 100000},
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{"250kHz (N2)", 250000},
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{"500kHz (WFM)", 500000},
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{"1MHz ", 1000000}};
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options_t freqman_entry_steps_short = {
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{"0.1kHz", 100},
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{"1kHz", 1000},
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{"5kHz", 5000},
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{"6.25kHz", 6250},
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{"8.33kHz", 8330},
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{"9kHz", 9000},
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{"10kHz", 10000},
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{"12.5kHz", 12500},
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{"15kHz", 15000},
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{"25kHz", 25000},
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{"30kHz", 30000},
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{"50kHz", 50000},
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{"100kHz", 100000},
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{"250kHz", 250000},
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{"500kHz", 500000},
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{"1MHz", 1000000}};
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bool load_freqman_file(std::string& file_stem, freqman_db& db, bool load_freqs, bool load_ranges, bool load_hamradios, uint8_t max_num_freqs) {
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// swap with empty vector to ensure memory is immediately released
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std::vector<freqman_entry>().swap(db);
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File freqman_file{};
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size_t length = 0, n = 0, file_position = 0;
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char* pos = NULL;
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char* line_start = NULL;
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char* line_end = NULL;
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std::string description{NULL};
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rf::Frequency frequency_a = 0, frequency_b = 0;
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char file_data[FREQMAN_READ_BUF_SIZE + 1] = {0};
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freqman_entry_type type = NOTYPE;
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freqman_index_t modulation = -1;
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freqman_index_t bandwidth = -1;
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freqman_index_t step = -1;
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freqman_index_t tone = -1;
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auto result = freqman_file.open("FREQMAN/" + file_stem + ".TXT");
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if (result.is_valid())
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return false;
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while (1) {
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// Read a FREQMAN_READ_BUF_SIZE block from file
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freqman_file.seek(file_position);
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memset(file_data, 0, FREQMAN_READ_BUF_SIZE + 1);
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auto read_size = freqman_file.read(file_data, FREQMAN_READ_BUF_SIZE);
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if (read_size.is_error())
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return false; // Read error
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file_position += FREQMAN_READ_BUF_SIZE;
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// Reset line_start to beginning of buffer
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line_start = file_data;
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// If EOF reached, insert 0x0A after, in case the last line doesn't have a C/R
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if (read_size.value() < FREQMAN_READ_BUF_SIZE)
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*(line_start + read_size.value()) = 0x0A;
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// Look for complete lines in buffer
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while ((line_end = strstr(line_start, "\x0A"))) {
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*line_end = 0; // Stop strstr() searches below at EOL
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modulation = -1;
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bandwidth = -1;
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step = -1;
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tone = -1;
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type = NOTYPE;
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frequency_a = frequency_b = 0;
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// Read frequency
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pos = strstr(line_start, "f=");
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if (pos) {
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pos += 2;
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frequency_a = strtoll(pos, nullptr, 10);
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type = SINGLE;
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} else {
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// ...or range
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pos = strstr(line_start, "a=");
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if (pos) {
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pos += 2;
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frequency_a = strtoll(pos, nullptr, 10);
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type = RANGE;
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pos = strstr(line_start, "b=");
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if (pos) {
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pos += 2;
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frequency_b = strtoll(pos, nullptr, 10);
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} else
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frequency_b = 0;
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} else {
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// ... or hamradio
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pos = strstr(line_start, "r=");
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if (pos) {
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pos += 2;
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frequency_a = strtoll(pos, nullptr, 10);
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type = HAMRADIO;
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pos = strstr(line_start, "t=");
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if (pos) {
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pos += 2;
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frequency_b = strtoll(pos, nullptr, 10);
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} else
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frequency_b = frequency_a;
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} else
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frequency_a = 0;
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}
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}
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// modulation if any
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pos = strstr(line_start, "m=");
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if (pos) {
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pos += 2;
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modulation = freqman_entry_get_modulation_from_str(pos);
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}
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// bandwidth if any
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pos = strstr(line_start, "bw=");
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if (pos) {
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pos += 3;
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bandwidth = freqman_entry_get_bandwidth_from_str(modulation, pos);
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}
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// step if any
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pos = strstr(line_start, "s=");
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if (pos) {
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pos += 2;
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step = freqman_entry_get_step_from_str_short(pos);
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}
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// ctcss tone if any
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/* disabled until better form
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pos = strstr(line_start, "c=");
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if (pos) {
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pos += 2;
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tone = tone_key_index_by_value( strtoll( pos , nullptr , 10 ) );
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} */
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// Read description until , or LF
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pos = strstr(line_start, "d=");
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if (pos) {
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pos += 2;
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length = std::min(strcspn(pos, ",\x0A"), (size_t)FREQMAN_DESC_MAX_LEN);
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description = string(pos, length);
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description.shrink_to_fit();
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}
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if ((type == SINGLE && load_freqs) || (type == RANGE && load_ranges) || (type == HAMRADIO && load_hamradios)) {
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freqman_entry entry = {frequency_a, frequency_b, std::move(description), type, modulation, bandwidth, step, tone};
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db.emplace_back(entry);
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n++;
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if (n > max_num_freqs) return true;
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}
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line_start = line_end + 1;
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if (line_start - file_data >= FREQMAN_READ_BUF_SIZE) break;
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}
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if (read_size.value() != FREQMAN_READ_BUF_SIZE)
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break; // End of file
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// Restart at beginning of last incomplete line
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file_position -= (file_data + FREQMAN_READ_BUF_SIZE - line_start);
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}
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/* populate implicitly specified modulation / bandwidth */
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if (db.size() > 2) {
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modulation = db[0].modulation;
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bandwidth = db[0].bandwidth;
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for (unsigned int it = 1; it < db.size(); it++) {
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if (db[it].modulation < 0) {
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db[it].modulation = modulation;
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} else {
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modulation = db[it].modulation;
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}
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if (db[it].bandwidth < 0) {
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db[it].bandwidth = bandwidth;
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} else {
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modulation = db[it].bandwidth;
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}
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}
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}
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db.shrink_to_fit();
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return true;
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}
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bool get_freq_string(freqman_entry& entry, std::string& item_string) {
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rf::Frequency frequency_a, frequency_b;
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frequency_a = entry.frequency_a;
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if (entry.type == SINGLE) {
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// Single
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item_string = "f=" + to_string_dec_uint(frequency_a / 1000) + to_string_dec_uint(frequency_a % 1000UL, 3, '0');
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} else if (entry.type == RANGE) {
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// Range
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frequency_b = entry.frequency_b;
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item_string = "a=" + to_string_dec_uint(frequency_a / 1000) + to_string_dec_uint(frequency_a % 1000UL, 3, '0');
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item_string += ",b=" + to_string_dec_uint(frequency_b / 1000) + to_string_dec_uint(frequency_b % 1000UL, 3, '0');
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if (entry.step >= 0) {
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item_string += ",s=" + freqman_entry_get_step_string_short(entry.step);
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}
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} else if (entry.type == HAMRADIO) {
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frequency_b = entry.frequency_b;
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item_string = "r=" + to_string_dec_uint(frequency_a / 1000) + to_string_dec_uint(frequency_a % 1000UL, 3, '0');
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item_string += ",t=" + to_string_dec_uint(frequency_b / 1000) + to_string_dec_uint(frequency_b % 1000UL, 3, '0');
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if (entry.tone >= 0) {
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item_string += ",c=" + tone_key_string(entry.tone);
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}
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}
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if (entry.modulation >= 0 && (unsigned)entry.modulation < freqman_entry_modulations.size()) {
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item_string += ",m=" + freqman_entry_get_modulation_string(entry.modulation);
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if (entry.bandwidth >= 0 && (unsigned)entry.bandwidth < freqman_entry_bandwidths[entry.modulation].size()) {
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item_string += ",bw=" + freqman_entry_get_bandwidth_string(entry.modulation, entry.bandwidth);
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}
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}
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if (entry.description.size())
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item_string += ",d=" + entry.description;
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return true;
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}
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bool delete_freqman_file(std::string& file_stem) {
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File freqman_file;
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std::string freq_file_path = "/FREQMAN/" + file_stem + ".TXT";
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delete_file(freq_file_path);
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return false;
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}
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bool save_freqman_file(std::string& file_stem, freqman_db& db) {
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File freqman_file;
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std::string freq_file_path = "/FREQMAN/" + file_stem + ".TXT";
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delete_file(freq_file_path);
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auto result = freqman_file.create(freq_file_path);
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if (!result.is_valid()) {
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for (size_t n = 0; n < db.size(); n++) {
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std::string line;
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get_freq_string(db[n], line);
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freqman_file.write_line(line);
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}
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return true;
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}
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return false;
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}
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bool create_freqman_file(std::string& file_stem, File& freqman_file) {
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auto result = freqman_file.create("FREQMAN/" + file_stem + ".TXT");
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if (result.is_valid())
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return false;
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return true;
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}
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std::string freqman_item_string(freqman_entry& entry, size_t max_length) {
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std::string item_string;
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switch (entry.type) {
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case SINGLE:
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item_string = to_string_short_freq(entry.frequency_a) + "M: " + entry.description;
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break;
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case RANGE:
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item_string = "R: " + entry.description;
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break;
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case HAMRADIO:
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item_string = "H: " + entry.description;
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break;
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default:
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item_string = "!UNKNOW TYPE " + entry.description;
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break;
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}
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if (item_string.size() > max_length)
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return item_string.substr(0, max_length - 3) + "...";
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return item_string;
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}
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void freqman_set_modulation_option(OptionsField& option) {
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option.set_options(freqman_entry_modulations);
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}
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void freqman_set_bandwidth_option(freqman_index_t modulation, OptionsField& option) {
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option.set_options(freqman_entry_bandwidths[modulation]);
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}
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void freqman_set_step_option(OptionsField& option) {
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option.set_options(freqman_entry_steps);
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}
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void freqman_set_step_option_short(OptionsField& option) {
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option.set_options(freqman_entry_steps_short);
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}
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std::string freqman_entry_get_modulation_string(freqman_index_t modulation) {
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if (modulation < 0 || (unsigned)modulation >= freqman_entry_modulations.size()) {
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return std::string(""); // unknown modulation
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}
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return freqman_entry_modulations[modulation].first;
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}
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std::string freqman_entry_get_bandwidth_string(freqman_index_t modulation, freqman_index_t bandwidth) {
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if (modulation < 0 || (unsigned)modulation >= freqman_entry_modulations.size()) {
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return std::string(""); // unknown modulation
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}
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if (bandwidth < 0 || (unsigned)bandwidth > freqman_entry_bandwidths[modulation].size()) {
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return std::string(""); // unknown modulation
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}
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return freqman_entry_bandwidths[modulation][bandwidth].first;
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}
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std::string freqman_entry_get_step_string(freqman_index_t step) {
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if (step < 0 || (unsigned)step >= freqman_entry_steps.size()) {
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return std::string(""); // unknown modulation
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}
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return freqman_entry_steps[step].first;
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}
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std::string freqman_entry_get_step_string_short(freqman_index_t step) {
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if (step < 0 || (unsigned)step >= freqman_entry_steps_short.size()) {
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return std::string(""); // unknown modulation
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}
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return freqman_entry_steps_short[step].first;
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}
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int32_t freqman_entry_get_modulation_value(freqman_index_t modulation) {
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if (modulation < 0 || (unsigned)modulation >= freqman_entry_modulations.size()) {
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return -1; // unknown modulation
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}
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return freqman_entry_modulations[modulation].second;
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}
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int32_t freqman_entry_get_bandwidth_value(freqman_index_t modulation, freqman_index_t bandwidth) {
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if (modulation < 0 || (unsigned)modulation >= freqman_entry_modulations.size()) {
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return -1; // unknown modulation
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}
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if (bandwidth < 0 || (unsigned)bandwidth > freqman_entry_bandwidths[modulation].size()) {
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return -1; // unknown bandwidth for modulation
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}
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return freqman_entry_bandwidths[modulation][bandwidth].second;
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}
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int32_t freqman_entry_get_step_value(freqman_index_t step) {
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if (step < 0 || (unsigned)step >= freqman_entry_steps.size()) {
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return -1; // unknown modulation
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}
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return freqman_entry_steps[step].second;
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}
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freqman_index_t freqman_entry_get_modulation_from_str(char* str) {
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if (!str)
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return -1;
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for (freqman_index_t index = 0; (unsigned)index < freqman_entry_modulations.size(); index++) {
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if (strncmp(freqman_entry_modulations[index].first.c_str(), str, freqman_entry_modulations[index].first.size()) == 0)
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return index;
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}
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return -1;
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}
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freqman_index_t freqman_entry_get_bandwidth_from_str(freqman_index_t modulation, char* str) {
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if (!str)
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return -1;
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if (modulation < 0 || (unsigned)modulation >= freqman_entry_modulations.size())
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return -1;
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for (freqman_index_t index = 0; (unsigned)index < freqman_entry_bandwidths[modulation].size(); index++) {
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if (strncmp(freqman_entry_bandwidths[modulation][index].first.c_str(), str, freqman_entry_bandwidths[modulation][index].first.size()) == 0)
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return index;
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}
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return -1;
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}
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freqman_index_t freqman_entry_get_step_from_str(char* str) {
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if (!str)
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return -1;
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for (freqman_index_t index = 0; (unsigned)index < freqman_entry_steps.size(); index++) {
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if (strncmp(freqman_entry_steps[index].first.c_str(), str, freqman_entry_steps[index].first.size()) == 0)
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return index;
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}
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return -1;
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}
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freqman_index_t freqman_entry_get_step_from_str_short(char* str) {
|
|
if (!str)
|
|
return -1;
|
|
for (freqman_index_t index = 0; (unsigned)index < freqman_entry_steps_short.size(); index++) {
|
|
if (strncmp(freqman_entry_steps_short[index].first.c_str(), str, freqman_entry_steps_short[index].first.size()) == 0)
|
|
return index;
|
|
}
|
|
return -1;
|
|
}
|