mayhem-firmware/firmware/application/ui_closecall.cpp
furrtek 6bcb7dc1b1 # This is a combination of 2 commits.
# The first commit's message is:

Updated RDS transmitter: flags, PI and date/time

Merging baseband audio tone generators

Merging DTMF baseband with "tones" baseband

Added stealth transmit mode

App flash section bumped to 512k
RX and TX LEDs are now used
Play dead should work again, added login option
Morse frame gen. for letters and fox hunt codes
Merged EPAR with Xylos
Made EPAR use encoders for frame gen.
Moved OOK encoders data in encoders.hpp
Simplified about screen, ui_about_demo.* files are still there

BHT city DB, keywords removed

BHT cities DB, keywords removed

Update README.md

RDS radiotext and time group generators

# This is the 2nd commit message:

Update README.md
2016-12-24 11:52:11 +01:00

394 lines
10 KiB
C++

/*
* Copyright (C) 2015 Jared Boone, ShareBrained Technology, Inc.
* Copyright (C) 2016 Furrtek
*
* This file is part of PortaPack.
*
* 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, 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; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#include "ui_closecall.hpp"
#include "msgpack.hpp"
#include "time.hpp"
#include "event_m0.hpp"
#include "portapack.hpp"
#include "baseband_api.hpp"
#include "string_format.hpp"
#include <cstring>
#include <stdio.h>
#include <algorithm>
using namespace portapack;
namespace ui {
void CloseCallView::focus() {
button_exit.focus();
}
CloseCallView::~CloseCallView() {
time::signal_tick_second -= signal_token_tick_second;
receiver_model.disable();
baseband::shutdown();
}
void CloseCallView::do_detection() {
uint8_t xmax = 0;
int64_t imax = 0;
uint16_t iraw = 0, c;
uint8_t power;
rf::Frequency freq_low, freq_high;
mean /= (CC_BIN_NB * slices_max);
// Find max value over threshold from all slices
for (c = 0; c < slices_max; c++) {
power = slicemax_db[c];
if (power >= min_threshold) {
if ((power - min_threshold >= mean) && (power > xmax)) {
xmax = power;
imax = slicemax_idx[c] + (c * CC_BIN_NB);
iraw = slicemax_idx[c];
}
}
}
// e-Message POCSAG FR:
// 466.025 MHz - 466.05 MHz - 466.075 MHz - 466.175 MHz - 466.20625 MHz - 466.23125 MHz
// 25 25 100 31 25
// Catches:
// 466.000
// 466.021 21
// 466.042 21
// 466.148 106
// 466.169 21
// 466.190 21
// Lock / release
if ((imax >= last_channel - 2) && (imax <= last_channel + 2) && imax) {
// Staying around the same frequency (+/- 25.4kHz)
if (detect_counter >= (5 / slices_max)) {
if ((imax != locked_imax) || (!locked)) {
std::string finalstr;
// 236 steps = 3.072MHz
// Resolution = 13.1kHz
if (locked) {
resolved_frequency = (resolved_frequency + slice_start + (CC_BIN_WIDTH * (imax - 118))) / 2; // Mean
} else {
resolved_frequency = slice_start + (CC_BIN_WIDTH * (imax - 118)); // Init
if ((resolved_frequency >= f_min) && (resolved_frequency <= f_max)) {
// Correct according to DC spike mask width (8 for now)
if (iraw > 118)
resolved_frequency -= (4 * CC_BIN_WIDTH);
else
resolved_frequency += (4 * CC_BIN_WIDTH);
text_infos.set("Locked !");
big_display.set_style(&style_locked);
big_display.set(resolved_frequency);
// Approximation/error display
freq_low = (resolved_frequency - 6000) / 1000;
freq_high = (resolved_frequency + 6000) / 1000;
finalstr = "~12kHz: " + to_string_dec_uint(freq_low / 1000) + "." + to_string_dec_uint(freq_low % 1000);
finalstr += "/" + to_string_dec_uint(freq_high / 1000) + "." + to_string_dec_uint(freq_high % 1000);
text_precision.set(finalstr);
locked = true;
locked_imax = imax;
}
}
//text_debug.set(to_string_dec_int(CC_BIN_WIDTH * (imax - 118)));
}
release_counter = 0;
} else {
detect_counter++;
}
} else {
detect_counter = 0;
if (locked) {
if (release_counter == 6) {
locked = false;
text_infos.set("Lost");
big_display.set_style(&style_grey);
big_display.set(resolved_frequency);
} else {
release_counter++;
}
}
}
last_channel = imax;
scan_counter++;
portapack::display.fill_rectangle({last_pos, 90, 1, 13}, Color::black());
last_pos = (ui::Coord)(iraw);
portapack::display.fill_rectangle({last_pos, 90, 1, 13}, Color::red());
}
void CloseCallView::on_channel_spectrum(const ChannelSpectrum& spectrum) {
uint8_t xmax = 0;
uint16_t imax = 0;
uint8_t threshold;
size_t i, m;
baseband::spectrum_streaming_stop();
// Draw spectrum line (for debug), 2 black pixels left and right
std::array<Color, 240> pixel_row;
for(i = 0; i < 118; i++) {
const auto pixel_color = spectrum_rgb3_lut[spectrum.db[256 - 120 + i]]; // 136~253 in 2~119
pixel_row[i + 2] = pixel_color;
}
for(i = 122; i < 240; i++) {
const auto pixel_color = spectrum_rgb3_lut[spectrum.db[i - 120]]; // 2~119 in 120~237
pixel_row[i - 2] = pixel_color;
}
display.draw_pixels(
{ { 0, 96 + slices_counter * 4 }, { pixel_row.size(), 1 } },
pixel_row
);
// Find max for this slice:
// Check if left of slice needs to be trimmed (masked)
//if (slices_counter == 0)
// i = slice_trim;
//else
i = 0;
for ( ; i < 118; i++) {
threshold = spectrum.db[256 - 120 + i]; // 128+8 = 136~254
if (threshold > xmax) {
xmax = threshold;
imax = i;
}
}
// Check if right of slice needs to be trimmed (masked)
if (slices_counter == (slices_max - 1))
m = 240 - slice_trim;
else
m = 240;
for (i = 122 ; i < m; i++) {
threshold = spectrum.db[i - 120]; // 240-120 = 120 -> +8 = 128
if (threshold > xmax) { // (0~2) 2~120 (120~136) 136~254 (254~256)
xmax = threshold;
imax = i - 4;
}
}
slicemax_db[slices_counter] = xmax;
slicemax_idx[slices_counter] = imax;
// Add to mean
for (i = 136; i < 254; i++)
mean += spectrum.db[i];
for (i = 2; i < 120; i++)
mean += spectrum.db[i];
// Slice update
if (slicing) {
if (slices_counter >= (slices_max - 1)) {
do_detection();
mean = 0;
slices_counter = 0;
} else {
slices_counter++;
}
slice_frequency = slice_start + (slices_counter * CC_SLICE_WIDTH);
receiver_model.set_tuning_frequency(slice_frequency);
} else {
do_detection();
}
baseband::spectrum_streaming_start();
}
void CloseCallView::on_show() {
baseband::spectrum_streaming_start();
}
void CloseCallView::on_hide() {
baseband::spectrum_streaming_stop();
}
void CloseCallView::on_range_changed() {
rf::Frequency slices_span;
rf::Frequency resolved_frequency;
int64_t offset;
f_max = field_frequency_max.value();
f_min = field_frequency_min.value();
scan_span = abs(f_max - f_min);
if (scan_span > CC_SLICE_WIDTH) {
// ex: 100~115 (15): 102.5(97.5~107.5) -> 112.5(107.5~117.5) = 2.5 lost left and right
slices_max = (scan_span + CC_SLICE_WIDTH - 1) / CC_SLICE_WIDTH;
slices_span = slices_max * CC_SLICE_WIDTH;
offset = ((scan_span - slices_span) / 2) + (CC_SLICE_WIDTH / 2);
slice_start = std::min(f_min, f_max) + offset;
slice_trim = 0;
slicing = true;
// Todo: trims
} else {
slice_frequency = (f_max + f_min) / 2;
slice_start = slice_frequency;
receiver_model.set_tuning_frequency(slice_frequency);
//resolved_frequency = (CC_SLICE_WIDTH - scan_span) / 2; // Trim frequency span (for both sides)
//resolved_frequency /= CC_BIN_WIDTH; // Convert to bin span
//slice_trim = resolved_frequency;
//portapack::display.fill_rectangle({0, 97, 240, 4}, Color::black());
//portapack::display.fill_rectangle({0, 97, slice_trim, 4}, Color::orange());
//portapack::display.fill_rectangle({240 - slice_trim, 97, slice_trim, 4}, Color::orange());
slices_max = 1;
slices_counter = 0;
slicing = false;
}
/*
f_min = field_frequency_min.value();
scan_span = 3000000;
slice_frequency = (f_min + 1500000);
slice_start = slice_frequency;
receiver_model.set_tuning_frequency(slice_frequency);
slice_trim = 0;
slices_max = 1;
slices_counter = 0;
slicing = false;
field_frequency_max.set_value(f_min + 3000000);
*/
text_slices.set(to_string_dec_int(slices_max));
slices_counter = 0;
}
void CloseCallView::on_lna_changed(int32_t v_db) {
receiver_model.set_lna(v_db);
}
void CloseCallView::on_vga_changed(int32_t v_db) {
receiver_model.set_vga(v_db);
}
void CloseCallView::on_tick_second() {
// Update scan rate indication
text_rate.set(to_string_dec_uint(scan_counter, 3));
scan_counter = 0;
}
CloseCallView::CloseCallView(
NavigationView& nav
)
{
baseband::run_image(portapack::spi_flash::image_tag_closecall);
add_children({ {
&text_labels_a,
&text_labels_b,
&text_labels_c,
&field_frequency_min,
&field_frequency_max,
&field_lna,
&field_vga,
&field_threshold,
&text_slices,
&text_rate,
&text_mhz,
&text_infos,
&text_precision,
&text_debug,
&big_display,
&button_exit
} });
text_labels_a.set_style(&style_grey);
text_labels_b.set_style(&style_grey);
text_labels_c.set_style(&style_grey);
text_slices.set_style(&style_grey);
text_rate.set_style(&style_grey);
text_mhz.set_style(&style_grey);
big_display.set_style(&style_grey);
// DEBUG
receiver_model.set_tuning_frequency(464400000);
field_threshold.set_value(80);
field_threshold.on_change = [this](int32_t v) {
min_threshold = v;
};
field_frequency_min.set_value(receiver_model.tuning_frequency());
field_frequency_min.set_step(100000);
field_frequency_min.on_change = [this](rf::Frequency f) {
(void)f;
this->on_range_changed();
};
field_frequency_min.on_edit = [this, &nav]() {
auto new_view = nav.push<FrequencyKeypadView>(receiver_model.tuning_frequency());
new_view->on_changed = [this](rf::Frequency f) {
//this->on_range_changed();
this->field_frequency_min.set_value(f);
};
};
field_frequency_max.set_value(receiver_model.tuning_frequency() + 2000000);
field_frequency_max.set_step(100000);
field_frequency_max.on_change = [this](rf::Frequency f) {
(void)f;
this->on_range_changed();
};
field_frequency_max.on_edit = [this, &nav]() {
auto new_view = nav.push<FrequencyKeypadView>(receiver_model.tuning_frequency());
new_view->on_changed = [this](rf::Frequency f) {
//this->on_range_changed();
this->field_frequency_max.set_value(f);
};
};
field_lna.set_value(receiver_model.lna());
field_lna.on_change = [this](int32_t v) {
this->on_lna_changed(v);
};
field_vga.set_value(receiver_model.vga());
field_vga.on_change = [this](int32_t v_db) {
this->on_vga_changed(v_db);
};
on_range_changed();
button_exit.on_select = [&nav](Button&){
nav.pop();
};
signal_token_tick_second = time::signal_tick_second += [this]() {
this->on_tick_second();
};
receiver_model.set_modulation(ReceiverModel::Mode::SpectrumAnalysis);
receiver_model.set_sampling_rate(3072000);
receiver_model.set_baseband_bandwidth(2500000);
receiver_model.enable();
}
} /* namespace ui */