#include "subghz_test_carrier.h" #include "../subghz_test_app_i.h" #include "../helpers/subghz_test_frequency.h" #include #include #include #include #include struct SubGhzTestCarrier { View* view; FuriTimer* timer; SubGhzTestCarrierCallback callback; // const SubGhzDevice* radio_device; void* context; }; typedef enum { SubGhzTestCarrierModelStatusRx, SubGhzTestCarrierModelStatusTx, } SubGhzTestCarrierModelStatus; typedef struct { uint8_t frequency; uint32_t real_frequency; FuriHalSubGhzPath path; float rssi; SubGhzTestCarrierModelStatus status; } SubGhzTestCarrierModel; void subghz_test_carrier_set_callback( SubGhzTestCarrier* subghz_test_carrier, SubGhzTestCarrierCallback callback, void* context) { furi_assert(subghz_test_carrier); furi_assert(callback); subghz_test_carrier->callback = callback; subghz_test_carrier->context = context; } void subghz_test_carrier_draw(Canvas* canvas, SubGhzTestCarrierModel* model) { char buffer[64]; canvas_set_color(canvas, ColorBlack); canvas_set_font(canvas, FontPrimary); canvas_draw_str(canvas, 0, 8, "CC1101 Basic Test"); canvas_set_font(canvas, FontSecondary); // Frequency snprintf( buffer, sizeof(buffer), "Freq: %03ld.%03ld.%03ld Hz", model->real_frequency / 1000000 % 1000, model->real_frequency / 1000 % 1000, model->real_frequency % 1000); canvas_draw_str(canvas, 0, 20, buffer); // Path char* path_name = "Unknown"; if(model->path == FuriHalSubGhzPathIsolate) { path_name = "isolate"; } else if(model->path == FuriHalSubGhzPath433) { path_name = "433MHz"; } else if(model->path == FuriHalSubGhzPath315) { path_name = "315MHz"; } else if(model->path == FuriHalSubGhzPath868) { path_name = "868MHz"; } snprintf(buffer, sizeof(buffer), "Path: %d - %s", model->path, path_name); canvas_draw_str(canvas, 0, 31, buffer); if(model->status == SubGhzTestCarrierModelStatusRx) { snprintf( buffer, sizeof(buffer), "RSSI: %ld.%ld dBm", (int32_t)(model->rssi), (int32_t)fabs(model->rssi * 10) % 10); canvas_draw_str(canvas, 0, 42, buffer); } else { canvas_draw_str(canvas, 0, 42, "TX"); } } bool subghz_test_carrier_input(InputEvent* event, void* context) { furi_assert(context); SubGhzTestCarrier* subghz_test_carrier = context; // const SubGhzDevice* radio_device = subghz_test_carrier->radio_device; if(event->key == InputKeyBack || event->type != InputTypeShort) { return false; } with_view_model( subghz_test_carrier->view, SubGhzTestCarrierModel * model, { furi_hal_subghz_idle(); // subghz_devices_idle(radio_device); if(event->key == InputKeyLeft) { if(model->frequency > 0) model->frequency--; } else if(event->key == InputKeyRight) { if(model->frequency < subghz_frequencies_count_testing - 1) model->frequency++; } else if(event->key == InputKeyDown) { if(model->path > 0) model->path--; } else if(event->key == InputKeyUp) { if(model->path < FuriHalSubGhzPath868) model->path++; } else if(event->key == InputKeyOk) { if(model->status == SubGhzTestCarrierModelStatusTx) { model->status = SubGhzTestCarrierModelStatusRx; } else { model->status = SubGhzTestCarrierModelStatusTx; } } model->real_frequency = furi_hal_subghz_set_frequency(subghz_frequencies_testing[model->frequency]); furi_hal_subghz_set_path(model->path); // model->real_frequency = subghz_devices_set_frequency( // radio_device, subghz_frequencies_testing[model->frequency]); if(model->status == SubGhzTestCarrierModelStatusRx) { furi_hal_gpio_init(&gpio_cc1101_g0, GpioModeInput, GpioPullNo, GpioSpeedLow); furi_hal_subghz_rx(); // furi_hal_gpio_init( // subghz_devices_get_data_gpio(radio_device), // GpioModeInput, // GpioPullNo, // GpioSpeedLow); // subghz_devices_set_rx(radio_device); } else { furi_hal_gpio_init( &gpio_cc1101_g0, GpioModeOutputPushPull, GpioPullNo, GpioSpeedLow); furi_hal_gpio_write(&gpio_cc1101_g0, true); if(!furi_hal_subghz_tx()) { furi_hal_gpio_init(&gpio_cc1101_g0, GpioModeInput, GpioPullNo, GpioSpeedLow); subghz_test_carrier->callback( SubGhzTestCarrierEventOnlyRx, subghz_test_carrier->context); } // if(!subghz_devices_set_tx(radio_device)) { // furi_hal_gpio_init( // subghz_devices_get_data_gpio(radio_device), // GpioModeInput, // GpioPullNo, // GpioSpeedLow); // subghz_test_carrier->callback( // SubGhzTestCarrierEventOnlyRx, subghz_test_carrier->context); // } } }, true); return true; } void subghz_test_carrier_enter(void* context) { furi_assert(context); SubGhzTestCarrier* subghz_test_carrier = context; // furi_assert(subghz_test_carrier->radio_device); // const SubGhzDevice* radio_device = subghz_test_carrier->radio_device; furi_hal_subghz_reset(); furi_hal_subghz_load_custom_preset(subghz_device_cc1101_preset_ook_650khz_async_regs); furi_hal_gpio_init(&gpio_cc1101_g0, GpioModeInput, GpioPullNo, GpioSpeedLow); // subghz_devices_reset(radio_device); // subghz_devices_load_preset(radio_device, FuriHalSubGhzPresetOok650Async, NULL); // furi_hal_gpio_init( // subghz_devices_get_data_gpio(radio_device), GpioModeInput, GpioPullNo, GpioSpeedLow); with_view_model( subghz_test_carrier->view, SubGhzTestCarrierModel * model, { model->frequency = subghz_frequencies_433_92_testing; // 433 model->real_frequency = furi_hal_subghz_set_frequency(subghz_frequencies_testing[model->frequency]); // model->real_frequency = subghz_devices_set_frequency( // radio_device, subghz_frequencies_testing[model->frequency]); model->path = FuriHalSubGhzPathIsolate; // isolate model->rssi = 0.0f; model->status = SubGhzTestCarrierModelStatusRx; }, true); furi_hal_subghz_rx(); // subghz_devices_set_rx(radio_device); furi_timer_start(subghz_test_carrier->timer, furi_kernel_get_tick_frequency() / 4); } void subghz_test_carrier_exit(void* context) { furi_assert(context); SubGhzTestCarrier* subghz_test_carrier = context; furi_timer_stop(subghz_test_carrier->timer); // Reinitialize IC to default state furi_hal_subghz_sleep(); // subghz_devices_sleep(subghz_test_carrier->radio_device); } void subghz_test_carrier_rssi_timer_callback(void* context) { furi_assert(context); SubGhzTestCarrier* subghz_test_carrier = context; with_view_model( subghz_test_carrier->view, SubGhzTestCarrierModel * model, { if(model->status == SubGhzTestCarrierModelStatusRx) { model->rssi = furi_hal_subghz_get_rssi(); // model->rssi = subghz_devices_get_rssi(subghz_test_carrier->radio_device); } }, false); } SubGhzTestCarrier* subghz_test_carrier_alloc() { SubGhzTestCarrier* subghz_test_carrier = malloc(sizeof(SubGhzTestCarrier)); // View allocation and configuration subghz_test_carrier->view = view_alloc(); view_allocate_model( subghz_test_carrier->view, ViewModelTypeLocking, sizeof(SubGhzTestCarrierModel)); view_set_context(subghz_test_carrier->view, subghz_test_carrier); view_set_draw_callback(subghz_test_carrier->view, (ViewDrawCallback)subghz_test_carrier_draw); view_set_input_callback(subghz_test_carrier->view, subghz_test_carrier_input); view_set_enter_callback(subghz_test_carrier->view, subghz_test_carrier_enter); view_set_exit_callback(subghz_test_carrier->view, subghz_test_carrier_exit); subghz_test_carrier->timer = furi_timer_alloc( subghz_test_carrier_rssi_timer_callback, FuriTimerTypePeriodic, subghz_test_carrier); return subghz_test_carrier; } void subghz_test_carrier_free(SubGhzTestCarrier* subghz_test_carrier) { furi_assert(subghz_test_carrier); furi_timer_free(subghz_test_carrier->timer); view_free(subghz_test_carrier->view); free(subghz_test_carrier); } View* subghz_test_carrier_get_view(SubGhzTestCarrier* subghz_test_carrier) { furi_assert(subghz_test_carrier); return subghz_test_carrier->view; } // void subghz_test_carrier_set_radio( // SubGhzTestCarrier* subghz_test_carrier, // const SubGhzDevice* radio_device) { // furi_assert(subghz_test_carrier); // subghz_test_carrier->radio_device = radio_device; // }