mirror of
https://github.com/eried/portapack-mayhem.git
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853ca2ef53
* Solve_low_bit_rate_150k_Capture_App * Applying review comments. * format issues * Adding back requested previous low bit rates
531 lines
16 KiB
C++
531 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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* Copyright (C) 2023 Kyle Reed
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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 "convert.hpp"
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#include "file.hpp"
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#include "file_reader.hpp"
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#include "freqman_db.hpp"
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#include "string_format.hpp"
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#include "tone_key.hpp"
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#include "utility.hpp"
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#include <array>
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#include <cctype>
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#include <string_view>
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#include <vector>
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namespace fs = std::filesystem;
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const std::filesystem::path freqman_dir{u"/FREQMAN"};
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const std::filesystem::path freqman_extension{u".TXT"};
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// NB: Don't include UI headers to keep this code unit testable.
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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_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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};
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options_t freqman_bandwidths[4] = {
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{
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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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},
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{
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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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{
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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 -- TODO: these should be indexes.
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{"12k5", 12500},
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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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{"150k", 150000},
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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}, /* We doubled x2 previous REC BW limit , now extended BW from 600k to 1M with fast enough SD card in C16 or C8 format .*/
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{"650k", 650000},
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{"750k", 750000},
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{"1000k", 1000000}, /* New limit bandwith option for recording in C16 (in fast SD card) or in C8 */
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{"1500k", 1500000}, /* From this BW onwards, the LCD is ok, but M4 CPU is having periodical sample rec dropps, (not real file size, accelerated replay) */
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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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};
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// TODO: these should be indexes.
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options_t freqman_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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};
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// TODO: these should be indexes.
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options_t freqman_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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};
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uint8_t find_by_name(const options_t& options, std::string_view name) {
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for (auto ix = 0u; ix < options.size(); ++ix)
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if (options[ix].first == name)
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return ix;
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return freqman_invalid_index;
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}
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const option_t* find_by_index(const options_t& options, freqman_index_t index) {
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if (index < options.size())
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return &options[index];
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else
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return nullptr;
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}
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/* Impl for next round of changes.
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*template <typename T, size_t N>
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*const T* find_by_name(const std::array<T, N>& info, std::string_view name) {
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* for (const auto& it : info) {
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* if (it.name == name)
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* return ⁢
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* }
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*
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* return nullptr;
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*}
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*/
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bool operator==(const freqman_entry& lhs, const freqman_entry& rhs) {
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auto equal = lhs.type == rhs.type &&
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lhs.frequency_a == rhs.frequency_a &&
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lhs.description == rhs.description &&
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lhs.modulation == rhs.modulation &&
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lhs.bandwidth == rhs.bandwidth;
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if (!equal)
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return false;
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if (lhs.type == freqman_type::Range) {
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equal = lhs.frequency_b == rhs.frequency_b &&
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lhs.step == rhs.step;
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} else if (lhs.type == freqman_type::HamRadio) {
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equal = lhs.frequency_b == rhs.frequency_b &&
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lhs.tone == rhs.tone;
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}
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return equal;
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}
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std::string freqman_entry_get_modulation_string(freqman_index_t modulation) {
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if (auto opt = find_by_index(freqman_modulations, modulation))
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return opt->first;
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return {};
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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 < freqman_modulations.size()) {
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if (auto opt = find_by_index(freqman_bandwidths[modulation], bandwidth))
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return opt->first;
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}
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return {};
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}
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std::string freqman_entry_get_step_string(freqman_index_t step) {
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if (auto opt = find_by_index(freqman_steps, step))
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return opt->first;
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return {};
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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 (auto opt = find_by_index(freqman_steps_short, step))
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return opt->first;
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return {};
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}
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const std::filesystem::path get_freqman_path(const std::string& stem) {
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return freqman_dir / stem + freqman_extension;
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}
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bool create_freqman_file(const std::string& file_stem) {
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auto fs_error = make_new_file(get_freqman_path(file_stem));
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return fs_error.ok();
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}
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bool load_freqman_file(const std::string& file_stem, freqman_db& db, freqman_load_options options) {
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return parse_freqman_file(get_freqman_path(file_stem), db, options);
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}
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void delete_freqman_file(const std::string& file_stem) {
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delete_file(get_freqman_path(file_stem));
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}
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std::string pretty_string(const freqman_entry& entry, size_t max_length) {
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std::string str;
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switch (entry.type) {
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case freqman_type::Single:
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str = to_string_short_freq(entry.frequency_a) + "M: " + entry.description;
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break;
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case freqman_type::Range:
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str = to_string_rounded_freq(entry.frequency_a, 1) + "M-" +
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to_string_rounded_freq(entry.frequency_b, 1) + "M: " + entry.description;
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break;
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case freqman_type::HamRadio:
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str = "R:" + to_string_rounded_freq(entry.frequency_a, 1) + "M,T:" +
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to_string_rounded_freq(entry.frequency_b, 1) + "M: " + entry.description;
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break;
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case freqman_type::Raw:
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str = entry.description;
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break;
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default:
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str = "UNK:" + entry.description;
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break;
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}
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// Truncate. '+' indicates if string has been truncated.
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if (str.size() > max_length)
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return str.substr(0, max_length - 1) + "+";
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return str;
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}
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std::string to_freqman_string(const freqman_entry& entry) {
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std::string serialized;
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serialized.reserve(0x80);
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// Append a key=value to the string.
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auto append_field = [&serialized](std::string_view name, std::string_view value) {
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if (!serialized.empty())
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serialized += ",";
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serialized += std::string{name} + "=" + std::string{value};
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};
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switch (entry.type) {
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case freqman_type::Single:
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append_field("f", to_string_dec_uint64(entry.frequency_a));
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break;
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case freqman_type::Range:
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append_field("a", to_string_dec_uint64(entry.frequency_a));
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append_field("b", to_string_dec_uint64(entry.frequency_b));
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if (is_valid(entry.step))
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append_field("s", freqman_entry_get_step_string_short(entry.step));
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break;
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case freqman_type::HamRadio:
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append_field("r", to_string_dec_uint64(entry.frequency_a));
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append_field("t", to_string_dec_uint64(entry.frequency_b));
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if (is_valid(entry.tone))
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append_field("c", tonekey::tone_key_value_string(entry.tone));
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break;
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case freqman_type::Raw:
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return entry.description;
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default:
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return {};
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};
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if (is_valid(entry.modulation) && entry.modulation < freqman_modulations.size()) {
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append_field("m", freqman_entry_get_modulation_string(entry.modulation));
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if (is_valid(entry.bandwidth) && (unsigned)entry.bandwidth < freqman_bandwidths[entry.modulation].size())
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append_field("bw", freqman_entry_get_bandwidth_string(entry.modulation, entry.bandwidth));
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}
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if (entry.description.size() > 0)
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append_field("d", entry.description);
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serialized.shrink_to_fit();
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return serialized;
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}
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freqman_index_t parse_tone_key(std::string_view value) {
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// Split into whole and fractional parts.
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auto parts = split_string(value, '.');
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int32_t tone_freq = 0;
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int32_t whole_part = 0;
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parse_int(parts[0], whole_part);
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// Tones are stored as frequency / 100 for some reason.
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// E.g. 14572 would be 145.7 (NB: 1s place is dropped).
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// TODO: Might be easier to just store the codes?
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// Multiply the whole part by 100 to get the tone frequency.
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tone_freq = whole_part * 100;
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// Add the fractional part, if present.
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if (parts.size() > 1) {
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auto c = parts[1].front();
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auto digit = std::isdigit(c) ? c - '0' : 0;
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tone_freq += digit * 10;
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}
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return static_cast<freqman_index_t>(tonekey::tone_key_index_by_value(tone_freq));
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}
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bool parse_freqman_entry(std::string_view str, freqman_entry& entry) {
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if (str.empty() || str[0] == '#')
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return false;
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entry = freqman_entry{};
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auto cols = split_string(str, ',');
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for (auto col : cols) {
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if (col.empty())
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continue;
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auto pair = split_string(col, '=');
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if (pair.size() != 2)
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continue;
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auto key = pair[0];
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auto value = pair[1];
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if (key == "a") {
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entry.type = freqman_type::Range;
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parse_int(value, entry.frequency_a);
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} else if (key == "b") {
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parse_int(value, entry.frequency_b);
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} else if (key == "bw") {
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// NB: Requires modulation to be set first
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if (entry.modulation < std::size(freqman_bandwidths)) {
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entry.bandwidth = find_by_name(freqman_bandwidths[entry.modulation], value);
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}
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} else if (key == "c") {
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entry.tone = parse_tone_key(value);
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} else if (key == "d") {
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entry.description = trim(value);
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} else if (key == "f") {
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entry.type = freqman_type::Single;
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parse_int(value, entry.frequency_a);
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} else if (key == "m") {
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entry.modulation = find_by_name(freqman_modulations, value);
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} else if (key == "r") {
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entry.type = freqman_type::HamRadio;
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parse_int(value, entry.frequency_a);
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} else if (key == "s") {
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entry.step = find_by_name(freqman_steps_short, value);
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} else if (key == "t") {
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parse_int(value, entry.frequency_b);
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}
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}
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return is_valid(entry);
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}
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bool parse_freqman_file(const fs::path& path, freqman_db& db, freqman_load_options options) {
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FreqmanDB freqman_db;
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freqman_db.set_read_raw(false); // Don't return malformed lines.
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if (!freqman_db.open(path))
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return false;
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// Attempt to avoid a re-alloc if possible.
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db.clear();
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db.reserve(freqman_db.entry_count());
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for (auto entry : freqman_db) {
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// Filter by entry type.
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if (entry.type == freqman_type::Unknown ||
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(entry.type == freqman_type::Single && !options.load_freqs) ||
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(entry.type == freqman_type::Range && !options.load_ranges) ||
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(entry.type == freqman_type::HamRadio && !options.load_hamradios)) {
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continue;
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}
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// Use previous entry's mod/band if current's aren't set.
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if (!db.empty()) {
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if (is_invalid(entry.modulation))
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entry.modulation = db.back()->modulation;
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if (is_invalid(entry.bandwidth))
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entry.bandwidth = db.back()->bandwidth;
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}
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// Move the entry onto the heap and push.
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db.push_back(std::make_unique<freqman_entry>(std::move(entry)));
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// Limit to max_entries when specified.
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if (options.max_entries > 0 && db.size() >= options.max_entries)
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break;
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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 is_valid(const freqman_entry& entry) {
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// No valid frequency combination was set.
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if (entry.type == freqman_type::Unknown)
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return false;
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// Frequency A must be set for all types
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if (entry.frequency_a == 0)
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return false;
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// Frequency B must be set for type Range or Ham Radio
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if (entry.type == freqman_type::Range || entry.type == freqman_type::HamRadio) {
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if (entry.frequency_b == 0)
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return false;
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}
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// Ranges should have frequencies A <= B.
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if (entry.type == freqman_type::Range) {
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if (entry.frequency_a > entry.frequency_b)
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return false;
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}
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// TODO: Consider additional validation:
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// - Tone only on HamRadio.
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// - Step only on Range
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// - Fail on failed parse_int.
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// - Fail if bandwidth set before modulation.
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return true;
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}
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/* FreqmanDB ***********************************/
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bool FreqmanDB::open(const std::filesystem::path& path, bool create) {
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auto result = FileWrapper::open(path, create);
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if (!result)
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return false;
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wrapper_ = *std::move(result);
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return true;
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}
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void FreqmanDB::close() {
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wrapper_.reset();
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}
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freqman_entry FreqmanDB::operator[](Index index) const {
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auto length = wrapper_->line_length(index);
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auto line_text = wrapper_->get_text(index, 0, length);
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if (line_text) {
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freqman_entry entry;
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if (parse_freqman_entry(*line_text, entry))
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return entry;
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else if (read_raw_) {
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entry.type = freqman_type::Raw;
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entry.description = trim(*line_text);
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return entry;
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}
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}
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return {};
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}
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void FreqmanDB::insert_entry(Index index, const freqman_entry& entry) {
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index = clip<uint32_t>(index, 0u, entry_count());
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wrapper_->insert_line(index);
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replace_entry(index, entry);
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}
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void FreqmanDB::append_entry(const freqman_entry& entry) {
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insert_entry(entry_count(), entry);
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}
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void FreqmanDB::replace_entry(Index index, const freqman_entry& entry) {
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auto range = wrapper_->line_range(index);
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if (!range)
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return;
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// Don't overwrite the '\n'.
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range->end--;
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wrapper_->replace_range(*range, to_freqman_string(entry));
|
|
}
|
|
|
|
void FreqmanDB::delete_entry(Index index) {
|
|
wrapper_->delete_line(index);
|
|
}
|
|
|
|
bool FreqmanDB::delete_entry(const freqman_entry& entry) {
|
|
auto it = find_entry(entry);
|
|
if (it == end())
|
|
return false;
|
|
|
|
delete_entry(it.index());
|
|
return true;
|
|
}
|
|
|
|
FreqmanDB::iterator FreqmanDB::find_entry(const freqman_entry& entry) {
|
|
return find_entry([&entry](const auto& other) {
|
|
return entry == other;
|
|
});
|
|
}
|
|
|
|
uint32_t FreqmanDB::entry_count() const {
|
|
// FileWrapper always presents a single line even for empty files.
|
|
return empty() ? 0u : wrapper_->line_count();
|
|
}
|
|
|
|
bool FreqmanDB::empty() const {
|
|
// FileWrapper always presents a single line even for empty files.
|
|
// A DB is only really empty if the file size is 0.
|
|
return !wrapper_ || wrapper_->size() == 0;
|
|
}
|