unleashed-firmware/applications/external/spectrum_analyzer/spectrum_analyzer.c
2023-04-24 01:56:43 +03:00

529 lines
No EOL
17 KiB
C

#include <furi.h>
#include <furi_hal.h>
#include <gui/gui.h>
#include <input/input.h>
#include <stdlib.h>
#include "spectrum_analyzer.h"
#include <lib/drivers/cc1101_regs.h>
#include "spectrum_analyzer_worker.h"
typedef struct {
uint16_t center_freq;
uint8_t width;
uint8_t band;
uint8_t vscroll;
uint32_t channel0_frequency;
uint32_t spacing;
bool mode_change;
float max_rssi;
uint8_t max_rssi_dec;
uint8_t max_rssi_channel;
uint8_t channel_ss[NUM_CHANNELS];
} SpectrumAnalyzerModel;
typedef struct {
SpectrumAnalyzerModel* model;
FuriMutex* model_mutex;
FuriMessageQueue* event_queue;
ViewPort* view_port;
Gui* gui;
SpectrumAnalyzerWorker* worker;
} SpectrumAnalyzer;
void spectrum_analyzer_draw_scale(Canvas* canvas, const SpectrumAnalyzerModel* model) {
// Draw line
canvas_draw_line(
canvas, FREQ_START_X, FREQ_BOTTOM_Y, FREQ_START_X + FREQ_LENGTH_X, FREQ_BOTTOM_Y);
// Draw minor scale
for(int i = FREQ_START_X; i < FREQ_START_X + FREQ_LENGTH_X; i += 5) {
canvas_draw_line(canvas, i, FREQ_BOTTOM_Y, i, FREQ_BOTTOM_Y + 2);
}
// Draw major scale
for(int i = FREQ_START_X; i < FREQ_START_X + FREQ_LENGTH_X; i += 25) {
canvas_draw_line(canvas, i, FREQ_BOTTOM_Y, i, FREQ_BOTTOM_Y + 4);
}
// Draw scale tags
uint16_t tag_left;
uint16_t tag_center;
uint16_t tag_right;
char temp_str[18];
tag_center = model->center_freq;
switch(model->width) {
case NARROW:
tag_left = model->center_freq - 2;
tag_right = model->center_freq + 2;
break;
case ULTRANARROW:
tag_left = model->center_freq - 1;
tag_right = model->center_freq + 1;
break;
case ULTRAWIDE:
tag_left = model->center_freq - 40;
tag_right = model->center_freq + 40;
break;
default:
tag_left = model->center_freq - 10;
tag_right = model->center_freq + 10;
}
canvas_set_font(canvas, FontSecondary);
snprintf(temp_str, 18, "%u", tag_left);
canvas_draw_str_aligned(canvas, FREQ_START_X, 63, AlignCenter, AlignBottom, temp_str);
snprintf(temp_str, 18, "%u", tag_center);
canvas_draw_str_aligned(canvas, 128 / 2, 63, AlignCenter, AlignBottom, temp_str);
snprintf(temp_str, 18, "%u", tag_right);
canvas_draw_str_aligned(
canvas, FREQ_START_X + FREQ_LENGTH_X - 1, 63, AlignCenter, AlignBottom, temp_str);
}
static void spectrum_analyzer_render_callback(Canvas* const canvas, void* ctx) {
SpectrumAnalyzer* spectrum_analyzer = ctx;
//furi_check(furi_mutex_acquire(spectrum_analyzer->model_mutex, FuriWaitForever) == FuriStatusOk);
SpectrumAnalyzerModel* model = spectrum_analyzer->model;
spectrum_analyzer_draw_scale(canvas, model);
for(uint8_t column = 0; column < 128; column++) {
uint8_t ss = model->channel_ss[column + 2];
// Compress height to max of 64 values (255>>2)
uint8_t s = MAX((ss - model->vscroll) >> 2, 0);
uint8_t y = FREQ_BOTTOM_Y - s; // bar height
// Draw each bar
canvas_draw_line(canvas, column, FREQ_BOTTOM_Y, column, y);
}
if(model->mode_change) {
char temp_mode_str[12];
switch(model->width) {
case NARROW:
strncpy(temp_mode_str, "NARROW", 12);
break;
case ULTRANARROW:
strncpy(temp_mode_str, "ULTRANARROW", 12);
break;
case ULTRAWIDE:
strncpy(temp_mode_str, "ULTRAWIDE", 12);
break;
default:
strncpy(temp_mode_str, "WIDE", 12);
break;
}
// Current mode label
char tmp_str[21];
snprintf(tmp_str, 21, "Mode: %s", temp_mode_str);
canvas_draw_str_aligned(canvas, 127, 4, AlignRight, AlignTop, tmp_str);
}
// Draw cross and label
if(model->max_rssi > PEAK_THRESHOLD) {
// Compress height to max of 64 values (255>>2)
uint8_t max_y = MAX((model->max_rssi_dec - model->vscroll) >> 2, 0);
max_y = (FREQ_BOTTOM_Y - max_y);
// Cross
int16_t x1, x2, y1, y2;
x1 = model->max_rssi_channel - 2 - 2;
if(x1 < 0) x1 = 0;
y1 = max_y - 2;
if(y1 < 0) y1 = 0;
x2 = model->max_rssi_channel - 2 + 2;
if(x2 > 127) x2 = 127;
y2 = max_y + 2;
if(y2 > 63) y2 = 63; // SHOULD NOT HAPPEN CHECK!
canvas_draw_line(canvas, x1, y1, x2, y2);
x1 = model->max_rssi_channel - 2 + 2;
if(x1 > 127) x1 = 127;
y1 = max_y - 2;
if(y1 < 0) y1 = 0;
x2 = model->max_rssi_channel - 2 - 2;
if(x2 < 0) x2 = 0;
y2 = max_y + 2;
if(y2 > 63) y2 = 63; // SHOULD NOT HAPPEN CHECK!
canvas_draw_line(canvas, (uint8_t)x1, (uint8_t)y1, (uint8_t)x2, (uint8_t)y2);
// Label
char temp_str[36];
snprintf(
temp_str,
36,
"Peak: %3.2f Mhz %3.1f dbm",
((double)(model->channel0_frequency + (model->max_rssi_channel * model->spacing)) /
1000000),
(double)model->max_rssi);
canvas_draw_str_aligned(canvas, 127, 0, AlignRight, AlignTop, temp_str);
}
//furi_mutex_release(spectrum_analyzer->model_mutex);
// FURI_LOG_D("Spectrum", "model->vscroll %u", model->vscroll);
}
static void spectrum_analyzer_input_callback(InputEvent* input_event, void* ctx) {
SpectrumAnalyzer* spectrum_analyzer = ctx;
// Only handle short presses
if(input_event->type == InputTypeShort) {
furi_message_queue_put(spectrum_analyzer->event_queue, input_event, FuriWaitForever);
}
}
static void spectrum_analyzer_worker_callback(
void* channel_ss,
float max_rssi,
uint8_t max_rssi_dec,
uint8_t max_rssi_channel,
void* context) {
SpectrumAnalyzer* spectrum_analyzer = context;
furi_check(
furi_mutex_acquire(spectrum_analyzer->model_mutex, FuriWaitForever) == FuriStatusOk);
SpectrumAnalyzerModel* model = (SpectrumAnalyzerModel*)spectrum_analyzer->model;
memcpy(model->channel_ss, (uint8_t*)channel_ss, sizeof(uint8_t) * NUM_CHANNELS);
model->max_rssi = max_rssi;
model->max_rssi_dec = max_rssi_dec;
model->max_rssi_channel = max_rssi_channel;
furi_mutex_release(spectrum_analyzer->model_mutex);
view_port_update(spectrum_analyzer->view_port);
}
void spectrum_analyzer_calculate_frequencies(SpectrumAnalyzerModel* model) {
// REDO ALL THIS. CALCULATE ONLY WITH SPACING!
uint8_t new_band;
uint32_t min_hz;
uint32_t max_hz;
uint8_t margin;
uint8_t step;
uint16_t upper_limit;
uint16_t lower_limit;
uint16_t next_up;
uint16_t next_down;
uint8_t next_band_up;
uint8_t next_band_down;
switch(model->width) {
case NARROW:
margin = NARROW_MARGIN;
step = NARROW_STEP;
model->spacing = NARROW_SPACING;
break;
case ULTRANARROW:
margin = ULTRANARROW_MARGIN;
step = ULTRANARROW_STEP;
model->spacing = ULTRANARROW_SPACING;
break;
case ULTRAWIDE:
margin = ULTRAWIDE_MARGIN;
step = ULTRAWIDE_STEP;
model->spacing = ULTRAWIDE_SPACING;
/* nearest 20 MHz step */
model->center_freq = ((model->center_freq + 10) / 20) * 20;
break;
default:
margin = WIDE_MARGIN;
step = WIDE_STEP;
model->spacing = WIDE_SPACING;
/* nearest 5 MHz step */
model->center_freq = ((model->center_freq + 2) / 5) * 5;
break;
}
/* handle cases near edges of bands */
if(model->center_freq > EDGE_900) {
new_band = BAND_900;
upper_limit = UPPER(MAX_900, margin, step);
lower_limit = LOWER(MIN_900, margin, step);
next_up = LOWER(MIN_300, margin, step);
next_down = UPPER(MAX_400, margin, step);
next_band_up = BAND_300;
next_band_down = BAND_400;
} else if(model->center_freq > EDGE_400) {
new_band = BAND_400;
upper_limit = UPPER(MAX_400, margin, step);
lower_limit = LOWER(MIN_400, margin, step);
next_up = LOWER(MIN_900, margin, step);
next_down = UPPER(MAX_300, margin, step);
next_band_up = BAND_900;
next_band_down = BAND_300;
} else {
new_band = BAND_300;
upper_limit = UPPER(MAX_300, margin, step);
lower_limit = LOWER(MIN_300, margin, step);
next_up = LOWER(MIN_400, margin, step);
next_down = UPPER(MAX_900, margin, step);
next_band_up = BAND_400;
next_band_down = BAND_900;
}
if(model->center_freq > upper_limit) {
model->center_freq = upper_limit;
if(new_band == model->band) {
new_band = next_band_up;
model->center_freq = next_up;
}
} else if(model->center_freq < lower_limit) {
model->center_freq = lower_limit;
if(new_band == model->band) {
new_band = next_band_down;
model->center_freq = next_down;
}
}
model->band = new_band;
/* doing everything in Hz from here on */
switch(model->band) {
case BAND_400:
min_hz = MIN_400 * 1000000;
max_hz = MAX_400 * 1000000;
break;
case BAND_300:
min_hz = MIN_300 * 1000000;
max_hz = MAX_300 * 1000000;
break;
default:
min_hz = MIN_900 * 1000000;
max_hz = MAX_900 * 1000000;
break;
}
model->channel0_frequency =
model->center_freq * 1000000 - (model->spacing * ((NUM_CHANNELS / 2) + 1));
// /* calibrate upper channels */
// hz = model->center_freq * 1000000;
// max_chan = NUM_CHANNELS / 2;
// while (hz <= max_hz && max_chan < NUM_CHANNELS) {
// instance->chan_table[max_chan].frequency = hz;
// FURI_LOG_T("Spectrum", "calibrate_freq ch[%u]: %lu", max_chan, hz);
// hz += model->spacing;
// max_chan++;
// }
// /* calibrate lower channels */
// hz = instance->freq * 1000000 - model->spacing;
// min_chan = NUM_CHANNELS / 2;
// while (hz >= min_hz && min_chan > 0) {
// min_chan--;
// instance->chan_table[min_chan].frequency = hz;
// FURI_LOG_T("Spectrum", "calibrate_freq ch[%u]: %lu", min_chan, hz);
// hz -= model->spacing;
// }
model->max_rssi = -200.0;
model->max_rssi_dec = 0;
FURI_LOG_D("Spectrum", "setup_frequencies - max_hz: %lu - min_hz: %lu", max_hz, min_hz);
FURI_LOG_D("Spectrum", "center_freq: %u", model->center_freq);
FURI_LOG_D(
"Spectrum",
"ch[0]: %lu - ch[%u]: %lu",
model->channel0_frequency,
NUM_CHANNELS - 1,
model->channel0_frequency + ((NUM_CHANNELS - 1) * model->spacing));
}
SpectrumAnalyzer* spectrum_analyzer_alloc() {
SpectrumAnalyzer* instance = malloc(sizeof(SpectrumAnalyzer));
instance->model = malloc(sizeof(SpectrumAnalyzerModel));
SpectrumAnalyzerModel* model = instance->model;
for(uint8_t ch = 0; ch < NUM_CHANNELS - 1; ch++) {
model->channel_ss[ch] = 0;
}
model->max_rssi_dec = 0;
model->max_rssi_channel = 0;
model->max_rssi = PEAK_THRESHOLD - 1; // Should initializar to < PEAK_THRESHOLD
model->center_freq = DEFAULT_FREQ;
model->width = WIDE;
model->band = BAND_400;
model->vscroll = DEFAULT_VSCROLL;
instance->model_mutex = furi_mutex_alloc(FuriMutexTypeNormal);
instance->event_queue = furi_message_queue_alloc(8, sizeof(InputEvent));
instance->worker = spectrum_analyzer_worker_alloc();
spectrum_analyzer_worker_set_callback(
instance->worker, spectrum_analyzer_worker_callback, instance);
// Set system callbacks
instance->view_port = view_port_alloc();
view_port_draw_callback_set(instance->view_port, spectrum_analyzer_render_callback, instance);
view_port_input_callback_set(instance->view_port, spectrum_analyzer_input_callback, instance);
// Open GUI and register view_port
instance->gui = furi_record_open(RECORD_GUI);
gui_add_view_port(instance->gui, instance->view_port, GuiLayerFullscreen);
return instance;
}
void spectrum_analyzer_free(SpectrumAnalyzer* instance) {
// view_port_enabled_set(view_port, false);
gui_remove_view_port(instance->gui, instance->view_port);
furi_record_close(RECORD_GUI);
view_port_free(instance->view_port);
spectrum_analyzer_worker_free(instance->worker);
furi_message_queue_free(instance->event_queue);
furi_mutex_free(instance->model_mutex);
free(instance->model);
free(instance);
furi_hal_subghz_idle();
furi_hal_subghz_sleep();
// Disable power for External CC1101 if it was enabled and module is connected
furi_hal_subghz_disable_ext_power();
// Reinit SPI handles for internal radio / nfc
furi_hal_subghz_init_radio_type(SubGhzRadioInternal);
}
int32_t spectrum_analyzer_app(void* p) {
UNUSED(p);
SpectrumAnalyzer* spectrum_analyzer = spectrum_analyzer_alloc();
InputEvent input;
// Enable power for External CC1101 if it is connected
furi_hal_subghz_enable_ext_power();
// Auto switch to internal radio if external radio is not available
furi_delay_ms(15);
if(!furi_hal_subghz_check_radio()) {
furi_hal_subghz_select_radio_type(SubGhzRadioInternal);
furi_hal_subghz_init_radio_type(SubGhzRadioInternal);
}
furi_hal_power_suppress_charge_enter();
FURI_LOG_D("Spectrum", "Main Loop - Starting worker");
furi_delay_ms(50);
spectrum_analyzer_worker_start(spectrum_analyzer->worker);
FURI_LOG_D("Spectrum", "Main Loop - Wait on queue");
furi_delay_ms(50);
while(furi_message_queue_get(spectrum_analyzer->event_queue, &input, FuriWaitForever) ==
FuriStatusOk) {
furi_check(
furi_mutex_acquire(spectrum_analyzer->model_mutex, FuriWaitForever) == FuriStatusOk);
FURI_LOG_D("Spectrum", "Main Loop - Input: %u", input.key);
SpectrumAnalyzerModel* model = spectrum_analyzer->model;
uint8_t vstep = VERTICAL_SHORT_STEP;
uint8_t hstep;
bool exit_loop = false;
switch(model->width) {
case NARROW:
hstep = NARROW_STEP;
break;
case ULTRANARROW:
hstep = ULTRANARROW_STEP;
break;
case ULTRAWIDE:
hstep = ULTRAWIDE_STEP;
break;
default:
hstep = WIDE_STEP;
break;
}
switch(input.key) {
case InputKeyUp:
model->vscroll = MAX(model->vscroll - vstep, MIN_VSCROLL);
FURI_LOG_D("Spectrum", "Vscroll: %u", model->vscroll);
break;
case InputKeyDown:
model->vscroll = MIN(model->vscroll + vstep, MAX_VSCROLL);
FURI_LOG_D("Spectrum", "Vscroll: %u", model->vscroll);
break;
case InputKeyRight:
model->center_freq += hstep;
FURI_LOG_D("Spectrum", "center_freq: %u", model->center_freq);
spectrum_analyzer_calculate_frequencies(model);
spectrum_analyzer_worker_set_frequencies(
spectrum_analyzer->worker, model->channel0_frequency, model->spacing, model->width);
break;
case InputKeyLeft:
model->center_freq -= hstep;
spectrum_analyzer_calculate_frequencies(model);
spectrum_analyzer_worker_set_frequencies(
spectrum_analyzer->worker, model->channel0_frequency, model->spacing, model->width);
FURI_LOG_D("Spectrum", "center_freq: %u", model->center_freq);
break;
case InputKeyOk: {
switch(model->width) {
case WIDE:
model->width = NARROW;
break;
case NARROW:
model->width = ULTRANARROW;
break;
case ULTRANARROW:
model->width = ULTRAWIDE;
break;
case ULTRAWIDE:
model->width = WIDE;
break;
default:
model->width = WIDE;
break;
}
}
model->mode_change = true;
view_port_update(spectrum_analyzer->view_port);
furi_delay_ms(1000);
model->mode_change = false;
spectrum_analyzer_calculate_frequencies(model);
spectrum_analyzer_worker_set_frequencies(
spectrum_analyzer->worker, model->channel0_frequency, model->spacing, model->width);
FURI_LOG_D("Spectrum", "Width: %u", model->width);
break;
case InputKeyBack:
exit_loop = true;
break;
default:
break;
}
furi_mutex_release(spectrum_analyzer->model_mutex);
view_port_update(spectrum_analyzer->view_port);
if(exit_loop == true) break;
}
spectrum_analyzer_worker_stop(spectrum_analyzer->worker);
furi_hal_power_suppress_charge_exit();
spectrum_analyzer_free(spectrum_analyzer);
return 0;
}