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VerstreuteSeele
2023-01-27 02:09:42 +01:00
parent 0879f92e3d
commit a2b797fe01
44 changed files with 1735 additions and 1623 deletions
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3
applications/plugins/dap_link/dap_link.c
View File

@@ -486,8 +486,7 @@ int32_t dap_link_app(void* p) {
if(furi_hal_usb_is_locked()) {
DialogsApp* dialogs = furi_record_open(RECORD_DIALOGS);
DialogMessage* message = dialog_message_alloc();
dialog_message_set_header(
message, "Connection\nis active!", 3, 2, AlignLeft, AlignTop);
dialog_message_set_header(message, "Connection\nis active!", 3, 2, AlignLeft, AlignTop);
dialog_message_set_text(
message,
"Disconnect from\nPC or phone to\nuse this function.",

1
applications/plugins/dice/dice.c
View File

@@ -467,7 +467,6 @@ int32_t dice_app(void* p) {
return 255;
}
ViewPort* view_port = view_port_alloc();
view_port_draw_callback_set(view_port, dice_render_callback, plugin_state);
view_port_input_callback_set(view_port, dice_input_callback, plugin_state->event_queue);

37
applications/plugins/orgasmotron/orgasmotron.c
View File

@@ -40,7 +40,7 @@ int32_t orgasmotron_app(void* p) {
PluginState* plugin_state = malloc(sizeof(PluginState));
ValueMutex state_mutex;
if (!init_mutex(&state_mutex, plugin_state, sizeof(PluginState))) {
if(!init_mutex(&state_mutex, plugin_state, sizeof(PluginState))) {
FURI_LOG_E("Orgasmatron", "cannot create mutex\r\n");
free(plugin_state);
return 255;
@@ -61,10 +61,10 @@ int32_t orgasmotron_app(void* p) {
//int mode = 0;
bool processing = true;
//while(furi_message_queue_get(event_queue, &event, FuriWaitForever) == FuriStatusOk) {
while (processing) {
while(processing) {
FuriStatus event_status = furi_message_queue_get(event_queue, &event, 100);
PluginState* plugin_state = (PluginState*)acquire_mutex_block(&state_mutex);
if (event_status == FuriStatusOk) {
if(event_status == FuriStatusOk) {
if(event.key == InputKeyBack && event.type == InputTypeShort) {
//Exit Application
notification_message(notification, &sequence_reset_vibro);
@@ -73,53 +73,58 @@ int32_t orgasmotron_app(void* p) {
processing = false;
//break;
}
if(event.key == InputKeyOk && (event.type == InputTypePress || event.type == InputTypeRelease)) {
if(event.key == InputKeyOk &&
(event.type == InputTypePress || event.type == InputTypeRelease)) {
plugin_state->mode = 0;
}
if(event.key == InputKeyLeft && (event.type == InputTypePress || event.type == InputTypeRelease)) {
if(event.key == InputKeyLeft &&
(event.type == InputTypePress || event.type == InputTypeRelease)) {
plugin_state->mode = 1;
}
if(event.key == InputKeyRight && (event.type == InputTypePress || event.type == InputTypeRelease)) {
if(event.key == InputKeyRight &&
(event.type == InputTypePress || event.type == InputTypeRelease)) {
plugin_state->mode = 3;
}
if(event.key == InputKeyUp && (event.type == InputTypePress || event.type == InputTypeRelease)) {
if(event.key == InputKeyUp &&
(event.type == InputTypePress || event.type == InputTypeRelease)) {
plugin_state->mode = 2;
}
if(event.key == InputKeyDown && (event.type == InputTypePress || event.type == InputTypeRelease)) {
if(event.key == InputKeyDown &&
(event.type == InputTypePress || event.type == InputTypeRelease)) {
plugin_state->mode = 4;
}
}
if (plugin_state->mode == 0) {
if(plugin_state->mode == 0) {
//Stop Vibration
notification_message(notification, &sequence_reset_vibro);
notification_message(notification, &sequence_reset_green);
} else if (plugin_state->mode == 1) {
} else if(plugin_state->mode == 1) {
//Full power
notification_message(notification, &sequence_set_vibro_on);
notification_message(notification, &sequence_set_green_255);
} else if (plugin_state->mode == 2) {
} else if(plugin_state->mode == 2) {
//Pulsed Vibration
notification_message(notification, &sequence_set_vibro_on);
notification_message(notification, &sequence_set_green_255);
delay(100);
notification_message(notification, &sequence_reset_vibro);
} else if (plugin_state->mode == 3) {
} else if(plugin_state->mode == 3) {
//Soft power
notification_message(notification, &sequence_set_vibro_on);
notification_message(notification, &sequence_set_green_255);
delay(50);
notification_message(notification, &sequence_reset_vibro);
} else if (plugin_state->mode == 4) {
} else if(plugin_state->mode == 4) {
//Special Sequence
for (int i = 0;i < 15;i++) {
for(int i = 0; i < 15; i++) {
notification_message(notification, &sequence_set_vibro_on);
notification_message(notification, &sequence_set_green_255);
delay(50);
notification_message(notification, &sequence_reset_vibro);
delay(50);
}
for (int i = 0;i < 2;i++) {
for(int i = 0; i < 2; i++) {
notification_message(notification, &sequence_set_vibro_on);
notification_message(notification, &sequence_set_green_255);
delay(400);

174
applications/plugins/protoview/app.c
View File

@@ -40,8 +40,8 @@ extern const SubGhzProtocolRegistry protoview_protocol_registry;
/* The callback actually just passes the control to the actual active
* view callback, after setting up basic stuff like cleaning the screen
* and setting color to black. */
static void render_callback(Canvas *const canvas, void *ctx) {
ProtoViewApp *app = ctx;
static void render_callback(Canvas* const canvas, void* ctx) {
ProtoViewApp* app = ctx;
/* Clear screen. */
canvas_set_color(canvas, ColorWhite);
@@ -51,14 +51,25 @@ static void render_callback(Canvas *const canvas, void *ctx) {
/* Call who is in charge right now. */
switch(app->current_view) {
case ViewRawPulses: render_view_raw_pulses(canvas,app); break;
case ViewInfo: render_view_info(canvas,app); break;
case ViewRawPulses:
render_view_raw_pulses(canvas, app);
break;
case ViewInfo:
render_view_info(canvas, app);
break;
case ViewFrequencySettings:
case ViewModulationSettings:
render_view_settings(canvas,app); break;
case ViewDirectSampling: render_view_direct_sampling(canvas,app); break;
case ViewBuildMessage: render_view_build_message(canvas,app); break;
default: furi_crash(TAG "Invalid view selected"); break;
render_view_settings(canvas, app);
break;
case ViewDirectSampling:
render_view_direct_sampling(canvas, app);
break;
case ViewBuildMessage:
render_view_build_message(canvas, app);
break;
default:
furi_crash(TAG "Invalid view selected");
break;
}
/* Draw the alert box if set. */
@@ -67,10 +78,9 @@ static void render_callback(Canvas *const canvas, void *ctx) {
/* Here all we do is putting the events into the queue that will be handled
* in the while() loop of the app entry point function. */
static void input_callback(InputEvent* input_event, void* ctx)
{
ProtoViewApp *app = ctx;
furi_message_queue_put(app->event_queue,input_event,FuriWaitForever);
static void input_callback(InputEvent* input_event, void* ctx) {
ProtoViewApp* app = ctx;
furi_message_queue_put(app->event_queue, input_event, FuriWaitForever);
}
/* Called to switch view (when left/right is pressed). Handles
@@ -80,15 +90,15 @@ static void input_callback(InputEvent* input_event, void* ctx)
* The 'switchto' parameter can be the identifier of a view, or the
* special views ViewGoNext and ViewGoPrev in order to move to
* the logical next/prev view. */
static void app_switch_view(ProtoViewApp *app, ProtoViewCurrentView switchto) {
static void app_switch_view(ProtoViewApp* app, ProtoViewCurrentView switchto) {
/* Switch to the specified view. */
ProtoViewCurrentView old = app->current_view;
if (switchto == ViewGoNext) {
if(switchto == ViewGoNext) {
app->current_view++;
if (app->current_view == ViewLast) app->current_view = 0;
} else if (switchto == ViewGoPrev) {
if (app->current_view == 0)
app->current_view = ViewLast-1;
if(app->current_view == ViewLast) app->current_view = 0;
} else if(switchto == ViewGoPrev) {
if(app->current_view == 0)
app->current_view = ViewLast - 1;
else
app->current_view--;
} else {
@@ -103,20 +113,20 @@ static void app_switch_view(ProtoViewApp *app, ProtoViewCurrentView switchto) {
/* Reset the view private data each time, before calling the enter/exit
* callbacks that may want to setup some state. */
memset(app->view_privdata,0,PROTOVIEW_VIEW_PRIVDATA_LEN);
memset(app->view_privdata, 0, PROTOVIEW_VIEW_PRIVDATA_LEN);
/* Call the enter/exit view callbacks if needed. */
if (old == ViewDirectSampling) view_exit_direct_sampling(app);
if (new == ViewDirectSampling) view_enter_direct_sampling(app);
if (old == ViewBuildMessage) view_exit_build_message(app);
if (new == ViewBuildMessage) view_enter_build_message(app);
if (old == ViewInfo) view_exit_info(app);
if(old == ViewDirectSampling) view_exit_direct_sampling(app);
if(new == ViewDirectSampling) view_enter_direct_sampling(app);
if(old == ViewBuildMessage) view_exit_build_message(app);
if(new == ViewBuildMessage) view_enter_build_message(app);
if(old == ViewInfo) view_exit_info(app);
/* The frequency/modulation settings are actually a single view:
* as long as the user stays between the two modes of this view we
* don't need to call the exit-view callback. */
if ((old == ViewFrequencySettings && new != ViewModulationSettings) ||
(old == ViewModulationSettings && new != ViewFrequencySettings))
if((old == ViewFrequencySettings && new != ViewModulationSettings) ||
(old == ViewModulationSettings && new != ViewFrequencySettings))
view_exit_settings(app);
ui_dismiss_alert(app);
@@ -125,7 +135,7 @@ static void app_switch_view(ProtoViewApp *app, ProtoViewCurrentView switchto) {
/* Allocate the application state and initialize a number of stuff.
* This is called in the entry point to create the application state. */
ProtoViewApp* protoview_app_alloc() {
ProtoViewApp *app = malloc(sizeof(ProtoViewApp));
ProtoViewApp* app = malloc(sizeof(ProtoViewApp));
// Init shared data structures
RawSamples = raw_samples_alloc();
@@ -148,10 +158,10 @@ ProtoViewApp* protoview_app_alloc() {
app->show_text_input = false;
app->alert_dismiss_time = 0;
app->current_view = ViewRawPulses;
for (int j = 0; j < ViewLast; j++) app->current_subview[j] = 0;
for(int j = 0; j < ViewLast; j++) app->current_subview[j] = 0;
app->direct_sampling_enabled = false;
app->view_privdata = malloc(PROTOVIEW_VIEW_PRIVDATA_LEN);
memset(app->view_privdata,0,PROTOVIEW_VIEW_PRIVDATA_LEN);
memset(app->view_privdata, 0, PROTOVIEW_VIEW_PRIVDATA_LEN);
// Signal found and visualization defaults
app->signal_bestlen = 0;
@@ -176,17 +186,14 @@ ProtoViewApp* protoview_app_alloc() {
app->txrx->environment = subghz_environment_alloc();
subghz_environment_set_protocol_registry(
app->txrx->environment, (void*)&protoview_protocol_registry);
app->txrx->receiver =
subghz_receiver_alloc_init(app->txrx->environment);
subghz_receiver_set_filter(app->txrx->receiver,
SubGhzProtocolFlag_Decodable);
app->txrx->receiver = subghz_receiver_alloc_init(app->txrx->environment);
subghz_receiver_set_filter(app->txrx->receiver, SubGhzProtocolFlag_Decodable);
subghz_worker_set_overrun_callback(
app->txrx->worker,
(SubGhzWorkerOverrunCallback)subghz_receiver_reset);
app->txrx->worker, (SubGhzWorkerOverrunCallback)subghz_receiver_reset);
subghz_worker_set_pair_callback(
app->txrx->worker, (SubGhzWorkerPairCallback)subghz_receiver_decode);
subghz_worker_set_context(app->txrx->worker, app->txrx->receiver);
app->frequency = subghz_setting_get_default_frequency(app->setting);
app->modulation = 0; /* Defaults to ProtoViewModulations[0]. */
@@ -199,7 +206,7 @@ ProtoViewApp* protoview_app_alloc() {
/* Free what the application allocated. It is not clear to me if the
* Flipper OS, once the application exits, will be able to reclaim space
* even if we forget to free something here. */
void protoview_app_free(ProtoViewApp *app) {
void protoview_app_free(ProtoViewApp* app) {
furi_assert(app);
// Put CC1101 on sleep, this also restores charging.
@@ -218,7 +225,7 @@ void protoview_app_free(ProtoViewApp *app) {
subghz_setting_free(app->setting);
// Worker stuff.
if (!app->txrx->debug_timer_sampling) {
if(!app->txrx->debug_timer_sampling) {
subghz_receiver_free(app->txrx->receiver);
subghz_environment_free(app->txrx->environment);
subghz_worker_free(app->txrx->worker);
@@ -236,8 +243,8 @@ void protoview_app_free(ProtoViewApp *app) {
/* Called periodically. Do signal processing here. Data we process here
* will be later displayed by the render callback. The side effect of this
* function is to scan for signals and set DetectedSamples. */
static void timer_callback(void *ctx) {
ProtoViewApp *app = ctx;
static void timer_callback(void* ctx) {
ProtoViewApp* app = ctx;
uint32_t delta, lastidx = app->signal_last_scan_idx;
/* scan_for_signal(), called by this function, deals with a
@@ -245,14 +252,14 @@ static void timer_callback(void *ctx) {
* cross-boundaries, it is enough if we scan each time the buffer fills
* for 50% more compared to the last scan. Thanks to this check we
* can avoid scanning too many times to just find the same data. */
if (lastidx < RawSamples->idx) {
if(lastidx < RawSamples->idx) {
delta = RawSamples->idx - lastidx;
} else {
delta = RawSamples->total - lastidx + RawSamples->idx;
}
if (delta < RawSamples->total/2) return;
if(delta < RawSamples->total / 2) return;
app->signal_last_scan_idx = RawSamples->idx;
scan_for_signal(app,RawSamples);
scan_for_signal(app, RawSamples);
}
/* This is the navigation callback we use in the view dispatcher used
@@ -265,7 +272,7 @@ static void timer_callback(void *ctx) {
* We just need a dummy callback returning false. We believe the
* implementation should be changed and if no callback is set, it should be
* the same as returning false. */
static bool keyboard_view_dispatcher_navigation_callback(void *ctx) {
static bool keyboard_view_dispatcher_navigation_callback(void* ctx) {
UNUSED(ctx);
return false;
}
@@ -273,10 +280,10 @@ static bool keyboard_view_dispatcher_navigation_callback(void *ctx) {
/* App entry point, as specified in application.fam. */
int32_t protoview_app_entry(void* p) {
UNUSED(p);
ProtoViewApp *app = protoview_app_alloc();
ProtoViewApp* app = protoview_app_alloc();
/* Create a timer. We do data analysis in the callback. */
FuriTimer *timer = furi_timer_alloc(timer_callback, FuriTimerTypePeriodic, app);
FuriTimer* timer = furi_timer_alloc(timer_callback, FuriTimerTypePeriodic, app);
furi_timer_start(timer, furi_kernel_get_tick_frequency() / 8);
/* Start listening to signals immediately. */
@@ -291,71 +298,68 @@ int32_t protoview_app_entry(void* p) {
InputEvent input;
while(app->running) {
FuriStatus qstat = furi_message_queue_get(app->event_queue, &input, 100);
if (qstat == FuriStatusOk) {
if (DEBUG_MSG) FURI_LOG_E(TAG, "Main Loop - Input: type %d key %u",
input.type, input.key);
if(qstat == FuriStatusOk) {
if(DEBUG_MSG)
FURI_LOG_E(TAG, "Main Loop - Input: type %d key %u", input.type, input.key);
/* Handle navigation here. Then handle view-specific inputs
* in the view specific handling function. */
if (input.type == InputTypeShort &&
input.key == InputKeyBack)
{
if (app->current_view != ViewRawPulses) {
if(input.type == InputTypeShort && input.key == InputKeyBack) {
if(app->current_view != ViewRawPulses) {
/* If this is not the main app view, go there. */
app_switch_view(app,ViewRawPulses);
app_switch_view(app, ViewRawPulses);
} else {
/* If we are in the main app view, warn the user
* they needs to long press to really quit. */
ui_show_alert(app,"Long press to exit",1000);
ui_show_alert(app, "Long press to exit", 1000);
}
} else if (input.type == InputTypeLong &&
input.key == InputKeyBack)
{
} else if(input.type == InputTypeLong && input.key == InputKeyBack) {
app->running = 0;
} else if (input.type == InputTypeShort &&
input.key == InputKeyRight &&
ui_get_current_subview(app) == 0)
{
} else if(
input.type == InputTypeShort && input.key == InputKeyRight &&
ui_get_current_subview(app) == 0) {
/* Go to the next view. */
app_switch_view(app,ViewGoNext);
} else if (input.type == InputTypeShort &&
input.key == InputKeyLeft &&
ui_get_current_subview(app) == 0)
{
app_switch_view(app, ViewGoNext);
} else if(
input.type == InputTypeShort && input.key == InputKeyLeft &&
ui_get_current_subview(app) == 0) {
/* Go to the previous view. */
app_switch_view(app,ViewGoPrev);
app_switch_view(app, ViewGoPrev);
} else {
/* This is where we pass the control to the currently
* active view input processing. */
switch(app->current_view) {
case ViewRawPulses:
process_input_raw_pulses(app,input);
process_input_raw_pulses(app, input);
break;
case ViewInfo:
process_input_info(app,input);
process_input_info(app, input);
break;
case ViewFrequencySettings:
case ViewModulationSettings:
process_input_settings(app,input);
process_input_settings(app, input);
break;
case ViewDirectSampling:
process_input_direct_sampling(app,input);
process_input_direct_sampling(app, input);
break;
case ViewBuildMessage:
process_input_build_message(app,input);
process_input_build_message(app, input);
break;
default:
furi_crash(TAG "Invalid view selected");
break;
default: furi_crash(TAG "Invalid view selected"); break;
}
}
} else {
/* Useful to understand if the app is still alive when it
* does not respond because of bugs. */
if (DEBUG_MSG) {
static int c = 0; c++;
if (!(c % 20)) FURI_LOG_E(TAG, "Loop timeout");
if(DEBUG_MSG) {
static int c = 0;
c++;
if(!(c % 20)) FURI_LOG_E(TAG, "Loop timeout");
}
}
if (app->show_text_input) {
if(app->show_text_input) {
/* Remove our viewport: we need to use a view dispatcher
* in order to show the standard Flipper keyboard. */
gui_remove_view_port(app->gui, app->view_port);
@@ -368,11 +372,11 @@ int32_t protoview_app_entry(void* p) {
* otherwise when the user presses back on the keyboard to
* abort, the dispatcher will not stop. */
view_dispatcher_set_navigation_event_callback(
app->view_dispatcher,
keyboard_view_dispatcher_navigation_callback);
app->view_dispatcher, keyboard_view_dispatcher_navigation_callback);
app->text_input = text_input_alloc();
view_dispatcher_set_event_callback_context(app->view_dispatcher,app);
view_dispatcher_add_view(app->view_dispatcher, 0, text_input_get_view(app->text_input));
view_dispatcher_set_event_callback_context(app->view_dispatcher, app);
view_dispatcher_add_view(
app->view_dispatcher, 0, text_input_get_view(app->text_input));
view_dispatcher_switch_to_view(app->view_dispatcher, 0);
/* Setup the text input view. The different parameters are set
@@ -388,7 +392,8 @@ int32_t protoview_app_entry(void* p) {
false);
/* Run the dispatcher with the keyboard. */
view_dispatcher_attach_to_gui(app->view_dispatcher, app->gui, ViewDispatcherTypeFullscreen);
view_dispatcher_attach_to_gui(
app->view_dispatcher, app->gui, ViewDispatcherTypeFullscreen);
view_dispatcher_run(app->view_dispatcher);
/* Undo all it: remove the view from the dispatcher, free it
@@ -406,7 +411,7 @@ int32_t protoview_app_entry(void* p) {
}
/* App no longer running. Shut down and free. */
if (app->txrx->txrx_state == TxRxStateRx) {
if(app->txrx->txrx_state == TxRxStateRx) {
FURI_LOG_E(TAG, "Putting CC1101 to sleep before exiting.");
radio_rx_end(app);
radio_sleep(app);
@@ -416,4 +421,3 @@ int32_t protoview_app_entry(void* p) {
protoview_app_free(app);
return 0;
}

266
applications/plugins/protoview/app.h
View File

@@ -66,11 +66,11 @@ typedef enum {
/* ================================== RX/TX ================================= */
typedef struct {
const char *name; // Name to show to the user.
const char *id; // Identifier in the Flipper API/file.
FuriHalSubGhzPreset preset; // The preset ID.
uint8_t *custom; // If not null, a set of registers for
// the CC1101, specifying a custom preset.
const char* name; // Name to show to the user.
const char* id; // Identifier in the Flipper API/file.
FuriHalSubGhzPreset preset; // The preset ID.
uint8_t* custom; // If not null, a set of registers for
// the CC1101, specifying a custom preset.
} ProtoViewModulation;
extern ProtoViewModulation ProtoViewModulations[]; /* In app_subghz.c */
@@ -79,19 +79,19 @@ extern ProtoViewModulation ProtoViewModulations[]; /* In app_subghz.c */
* It receives data and we get our protocol "feed" callback called
* with the level (1 or 0) and duration. */
struct ProtoViewTxRx {
bool freq_mod_changed; /* The user changed frequency and/or modulation
bool freq_mod_changed; /* The user changed frequency and/or modulation
from the interface. There is to restart the
radio with the right parameters. */
SubGhzWorker* worker; /* Our background worker. */
SubGhzWorker* worker; /* Our background worker. */
SubGhzEnvironment* environment;
SubGhzReceiver* receiver;
TxRxState txrx_state; /* Receiving, idle or sleeping? */
/* Timer sampling mode state. */
bool debug_timer_sampling; /* Read data from GDO0 in a busy loop. Only
bool debug_timer_sampling; /* Read data from GDO0 in a busy loop. Only
for testing. */
uint32_t last_g0_change_time; /* Last high->low (or reverse) switch. */
bool last_g0_value; /* Current value (high or low): we are
bool last_g0_value; /* Current value (high or low): we are
checking the duration in the timer
handler. */
};
@@ -103,44 +103,44 @@ typedef struct ProtoViewTxRx ProtoViewTxRx;
#define ALERT_MAX_LEN 32
struct ProtoViewApp {
/* GUI */
Gui *gui;
NotificationApp *notification;
ViewPort *view_port; /* We just use a raw viewport and we render
Gui* gui;
NotificationApp* notification;
ViewPort* view_port; /* We just use a raw viewport and we render
everything into the low level canvas. */
ProtoViewCurrentView current_view; /* Active left-right view ID. */
int current_subview[ViewLast]; /* Active up-down subview ID. */
FuriMessageQueue *event_queue; /* Keypress events go here. */
ProtoViewCurrentView current_view; /* Active left-right view ID. */
int current_subview[ViewLast]; /* Active up-down subview ID. */
FuriMessageQueue* event_queue; /* Keypress events go here. */
/* Input text state. */
ViewDispatcher *view_dispatcher; /* Used only when we want to show
ViewDispatcher* view_dispatcher; /* Used only when we want to show
the text_input view for a moment.
Otherwise it is set to null. */
TextInput *text_input;
TextInput* text_input;
bool show_text_input;
char *text_input_buffer;
char* text_input_buffer;
uint32_t text_input_buffer_len;
void (*text_input_done_callback)(void*);
/* Alert state. */
uint32_t alert_dismiss_time; /* Millisecond when the alert will be
uint32_t alert_dismiss_time; /* Millisecond when the alert will be
no longer shown. Or zero if the alert
is currently not set at all. */
char alert_text[ALERT_MAX_LEN]; /* Alert content. */
/* Radio related. */
ProtoViewTxRx *txrx; /* Radio state. */
SubGhzSetting *setting; /* A list of valid frequencies. */
ProtoViewTxRx* txrx; /* Radio state. */
SubGhzSetting* setting; /* A list of valid frequencies. */
/* Generic app state. */
int running; /* Once false exists the app. */
int running; /* Once false exists the app. */
uint32_t signal_bestlen; /* Longest coherent signal observed so far. */
uint32_t signal_last_scan_idx; /* Index of the buffer last time we
performed the scan. */
bool signal_decoded; /* Was the current signal decoded? */
ProtoViewMsgInfo *msg_info; /* Decoded message info if not NULL. */
bool signal_decoded; /* Was the current signal decoded? */
ProtoViewMsgInfo* msg_info; /* Decoded message info if not NULL. */
bool direct_sampling_enabled; /* This special view needs an explicit
acknowledge to work. */
void *view_privdata; /* This is a piece of memory of total size
void* view_privdata; /* This is a piece of memory of total size
PROTOVIEW_VIEW_PRIVDATA_LEN that it is
initialized to zero when we switch to
a a new view. While the view we are using
@@ -149,12 +149,12 @@ struct ProtoViewApp {
the pointer to a few specific-data structure. */
/* Raw view apps state. */
uint32_t us_scale; /* microseconds per pixel. */
uint32_t signal_offset; /* Long press left/right panning in raw view. */
uint32_t us_scale; /* microseconds per pixel. */
uint32_t signal_offset; /* Long press left/right panning in raw view. */
/* Configuration view app state. */
uint32_t frequency; /* Current frequency. */
uint8_t modulation; /* Current modulation ID, array index in the
uint32_t frequency; /* Current frequency. */
uint8_t modulation; /* Current modulation ID, array index in the
ProtoViewModulations table. */
};
@@ -165,18 +165,18 @@ struct ProtoViewApp {
* in the message info view. */
#define PROTOVIEW_MSG_STR_LEN 32
typedef struct ProtoViewMsgInfo {
ProtoViewDecoder *decoder; /* The decoder that decoded the message. */
ProtoViewFieldSet *fieldset; /* Decoded fields. */
ProtoViewDecoder* decoder; /* The decoder that decoded the message. */
ProtoViewFieldSet* fieldset; /* Decoded fields. */
/* Low level information of the detected signal: the following are filled
* by the protocol decoding function: */
uint32_t start_off; /* Pulses start offset in the bitmap. */
uint32_t pulses_count; /* Number of pulses of the full message. */
uint32_t start_off; /* Pulses start offset in the bitmap. */
uint32_t pulses_count; /* Number of pulses of the full message. */
/* The following are passed already filled to the decoder. */
uint32_t short_pulse_dur; /* Microseconds duration of the short pulse. */
uint32_t short_pulse_dur; /* Microseconds duration of the short pulse. */
/* The following are filled by ProtoView core after the decoder returned
* success. */
uint8_t *bits; /* Bitmap with the signal. */
uint32_t bits_bytes; /* Number of full bytes in the bitmap, that
uint8_t* bits; /* Bitmap with the signal. */
uint32_t bits_bytes; /* Number of full bytes in the bitmap, that
is 'pulses_count/8' rounded to the next
integer. */
} ProtoViewMsgInfo;
@@ -196,28 +196,28 @@ typedef enum {
typedef struct {
ProtoViewFieldType type;
uint32_t len; // Depends on type:
// Bits for integers (signed,unsigned,binary,hex).
// Number of characters for strings.
// Number of nibbles for bytes (1 for each 4 bits).
// Number of digits after dot for floats.
char *name; // Field name.
uint32_t len; // Depends on type:
// Bits for integers (signed,unsigned,binary,hex).
// Number of characters for strings.
// Number of nibbles for bytes (1 for each 4 bits).
// Number of digits after dot for floats.
char* name; // Field name.
union {
char *str; // String type.
int64_t value; // Signed integer type.
uint64_t uvalue; // Unsigned integer type.
uint8_t *bytes; // Raw bytes type.
float fvalue; // Float type.
char* str; // String type.
int64_t value; // Signed integer type.
uint64_t uvalue; // Unsigned integer type.
uint8_t* bytes; // Raw bytes type.
float fvalue; // Float type.
};
} ProtoViewField;
typedef struct ProtoViewFieldSet {
ProtoViewField **fields;
ProtoViewField** fields;
uint32_t numfields;
} ProtoViewFieldSet;
typedef struct ProtoViewDecoder {
const char *name; /* Protocol name. */
const char* name; /* Protocol name. */
/* The decode function takes a buffer that is actually a bitmap, with
* high and low levels represented as 0 and 1. The number of high/low
* pulses represented by the bitmap is passed as the 'numbits' argument,
@@ -225,15 +225,15 @@ typedef struct ProtoViewDecoder {
* 'bits'. So 'numbytes' is mainly useful to pass as argument to other
* functions that perform bit extraction with bound checking, such as
* bitmap_get() and so forth. */
bool (*decode)(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info);
bool (*decode)(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info);
/* This method is used by the decoder to return the fields it needs
* in order to build a new message. This way the message builder view
* can ask the user to fill the right set of fields of the specified
* type. */
void (*get_fields)(ProtoViewFieldSet *fields);
void (*get_fields)(ProtoViewFieldSet* fields);
/* This method takes the fields supported by the decoder, and
* renders a message in 'samples'. */
void (*build_message)(RawSamplesBuffer *samples, ProtoViewFieldSet *fields);
void (*build_message)(RawSamplesBuffer* samples, ProtoViewFieldSet* fields);
} ProtoViewDecoder;
extern RawSamplesBuffer *RawSamples, *DetectedSamples;
@@ -244,76 +244,118 @@ uint32_t radio_rx(ProtoViewApp* app);
void radio_idle(ProtoViewApp* app);
void radio_rx_end(ProtoViewApp* app);
void radio_sleep(ProtoViewApp* app);
void raw_sampling_worker_start(ProtoViewApp *app);
void raw_sampling_worker_stop(ProtoViewApp *app);
void radio_tx_signal(ProtoViewApp *app, FuriHalSubGhzAsyncTxCallback data_feeder, void *ctx);
void raw_sampling_worker_start(ProtoViewApp* app);
void raw_sampling_worker_stop(ProtoViewApp* app);
void radio_tx_signal(ProtoViewApp* app, FuriHalSubGhzAsyncTxCallback data_feeder, void* ctx);
/* signal.c */
uint32_t duration_delta(uint32_t a, uint32_t b);
void reset_current_signal(ProtoViewApp *app);
void scan_for_signal(ProtoViewApp *app,RawSamplesBuffer *source);
bool bitmap_get(uint8_t *b, uint32_t blen, uint32_t bitpos);
void bitmap_set(uint8_t *b, uint32_t blen, uint32_t bitpos, bool val);
void bitmap_copy(uint8_t *d, uint32_t dlen, uint32_t doff, uint8_t *s, uint32_t slen, uint32_t soff, uint32_t count);
void bitmap_set_pattern(uint8_t *b, uint32_t blen, uint32_t off, const char *pat);
void bitmap_reverse_bytes_bits(uint8_t *p, uint32_t len);
bool bitmap_match_bits(uint8_t *b, uint32_t blen, uint32_t bitpos, const char *bits);
uint32_t bitmap_seek_bits(uint8_t *b, uint32_t blen, uint32_t startpos, uint32_t maxbits, const char *bits);
uint32_t convert_from_line_code(uint8_t *buf, uint64_t buflen, uint8_t *bits, uint32_t len, uint32_t offset, const char *zero_pattern, const char *one_pattern);
uint32_t convert_from_diff_manchester(uint8_t *buf, uint64_t buflen, uint8_t *bits, uint32_t len, uint32_t off, bool previous);
void init_msg_info(ProtoViewMsgInfo *i, ProtoViewApp *app);
void free_msg_info(ProtoViewMsgInfo *i);
void reset_current_signal(ProtoViewApp* app);
void scan_for_signal(ProtoViewApp* app, RawSamplesBuffer* source);
bool bitmap_get(uint8_t* b, uint32_t blen, uint32_t bitpos);
void bitmap_set(uint8_t* b, uint32_t blen, uint32_t bitpos, bool val);
void bitmap_copy(
uint8_t* d,
uint32_t dlen,
uint32_t doff,
uint8_t* s,
uint32_t slen,
uint32_t soff,
uint32_t count);
void bitmap_set_pattern(uint8_t* b, uint32_t blen, uint32_t off, const char* pat);
void bitmap_reverse_bytes_bits(uint8_t* p, uint32_t len);
bool bitmap_match_bits(uint8_t* b, uint32_t blen, uint32_t bitpos, const char* bits);
uint32_t bitmap_seek_bits(
uint8_t* b,
uint32_t blen,
uint32_t startpos,
uint32_t maxbits,
const char* bits);
uint32_t convert_from_line_code(
uint8_t* buf,
uint64_t buflen,
uint8_t* bits,
uint32_t len,
uint32_t offset,
const char* zero_pattern,
const char* one_pattern);
uint32_t convert_from_diff_manchester(
uint8_t* buf,
uint64_t buflen,
uint8_t* bits,
uint32_t len,
uint32_t off,
bool previous);
void init_msg_info(ProtoViewMsgInfo* i, ProtoViewApp* app);
void free_msg_info(ProtoViewMsgInfo* i);
/* signal_file.c */
bool save_signal(ProtoViewApp *app, const char *filename);
bool save_signal(ProtoViewApp* app, const char* filename);
/* view_*.c */
void render_view_raw_pulses(Canvas *const canvas, ProtoViewApp *app);
void process_input_raw_pulses(ProtoViewApp *app, InputEvent input);
void render_view_settings(Canvas *const canvas, ProtoViewApp *app);
void process_input_settings(ProtoViewApp *app, InputEvent input);
void render_view_info(Canvas *const canvas, ProtoViewApp *app);
void process_input_info(ProtoViewApp *app, InputEvent input);
void render_view_direct_sampling(Canvas *const canvas, ProtoViewApp *app);
void process_input_direct_sampling(ProtoViewApp *app, InputEvent input);
void render_view_build_message(Canvas *const canvas, ProtoViewApp *app);
void process_input_build_message(ProtoViewApp *app, InputEvent input);
void view_enter_build_message(ProtoViewApp *app);
void view_exit_build_message(ProtoViewApp *app);
void view_enter_direct_sampling(ProtoViewApp *app);
void view_exit_direct_sampling(ProtoViewApp *app);
void view_exit_settings(ProtoViewApp *app);
void view_exit_info(ProtoViewApp *app);
void adjust_raw_view_scale(ProtoViewApp *app, uint32_t short_pulse_dur);
void render_view_raw_pulses(Canvas* const canvas, ProtoViewApp* app);
void process_input_raw_pulses(ProtoViewApp* app, InputEvent input);
void render_view_settings(Canvas* const canvas, ProtoViewApp* app);
void process_input_settings(ProtoViewApp* app, InputEvent input);
void render_view_info(Canvas* const canvas, ProtoViewApp* app);
void process_input_info(ProtoViewApp* app, InputEvent input);
void render_view_direct_sampling(Canvas* const canvas, ProtoViewApp* app);
void process_input_direct_sampling(ProtoViewApp* app, InputEvent input);
void render_view_build_message(Canvas* const canvas, ProtoViewApp* app);
void process_input_build_message(ProtoViewApp* app, InputEvent input);
void view_enter_build_message(ProtoViewApp* app);
void view_exit_build_message(ProtoViewApp* app);
void view_enter_direct_sampling(ProtoViewApp* app);
void view_exit_direct_sampling(ProtoViewApp* app);
void view_exit_settings(ProtoViewApp* app);
void view_exit_info(ProtoViewApp* app);
void adjust_raw_view_scale(ProtoViewApp* app, uint32_t short_pulse_dur);
/* ui.c */
int ui_get_current_subview(ProtoViewApp *app);
void ui_show_available_subviews(Canvas *canvas, ProtoViewApp *app, int last_subview);
bool ui_process_subview_updown(ProtoViewApp *app, InputEvent input, int last_subview);
void ui_show_keyboard(ProtoViewApp *app, char *buffer, uint32_t buflen,
void (*done_callback)(void*));
void ui_dismiss_keyboard(ProtoViewApp *app);
void ui_show_alert(ProtoViewApp *app, const char *text, uint32_t ttl);
void ui_dismiss_alert(ProtoViewApp *app);
void ui_draw_alert_if_needed(Canvas *canvas, ProtoViewApp *app);
void canvas_draw_str_with_border(Canvas* canvas, uint8_t x, uint8_t y, const char* str, Color text_color, Color border_color);
int ui_get_current_subview(ProtoViewApp* app);
void ui_show_available_subviews(Canvas* canvas, ProtoViewApp* app, int last_subview);
bool ui_process_subview_updown(ProtoViewApp* app, InputEvent input, int last_subview);
void ui_show_keyboard(
ProtoViewApp* app,
char* buffer,
uint32_t buflen,
void (*done_callback)(void*));
void ui_dismiss_keyboard(ProtoViewApp* app);
void ui_show_alert(ProtoViewApp* app, const char* text, uint32_t ttl);
void ui_dismiss_alert(ProtoViewApp* app);
void ui_draw_alert_if_needed(Canvas* canvas, ProtoViewApp* app);
void canvas_draw_str_with_border(
Canvas* canvas,
uint8_t x,
uint8_t y,
const char* str,
Color text_color,
Color border_color);
/* fields.c */
void fieldset_free(ProtoViewFieldSet *fs);
ProtoViewFieldSet *fieldset_new(void);
void fieldset_add_int(ProtoViewFieldSet *fs, const char *name, int64_t val, uint8_t bits);
void fieldset_add_uint(ProtoViewFieldSet *fs, const char *name, uint64_t uval, uint8_t bits);
void fieldset_add_hex(ProtoViewFieldSet *fs, const char *name, uint64_t uval, uint8_t bits);
void fieldset_add_bin(ProtoViewFieldSet *fs, const char *name, uint64_t uval, uint8_t bits);
void fieldset_add_str(ProtoViewFieldSet *fs, const char *name, const char *s);
void fieldset_add_bytes(ProtoViewFieldSet *fs, const char *name, const uint8_t *bytes, uint32_t count);
void fieldset_add_float(ProtoViewFieldSet *fs, const char *name, float val, uint32_t digits_after_dot);
const char *field_get_type_name(ProtoViewField *f);
int field_to_string(char *buf, size_t len, ProtoViewField *f);
bool field_set_from_string(ProtoViewField *f, char *buf, size_t len);
bool field_incr_value(ProtoViewField *f, int incr);
void fieldset_copy_matching_fields(ProtoViewFieldSet *dst, ProtoViewFieldSet *src);
void field_set_from_field(ProtoViewField *dst, ProtoViewField *src);
void fieldset_free(ProtoViewFieldSet* fs);
ProtoViewFieldSet* fieldset_new(void);
void fieldset_add_int(ProtoViewFieldSet* fs, const char* name, int64_t val, uint8_t bits);
void fieldset_add_uint(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits);
void fieldset_add_hex(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits);
void fieldset_add_bin(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits);
void fieldset_add_str(ProtoViewFieldSet* fs, const char* name, const char* s);
void fieldset_add_bytes(
ProtoViewFieldSet* fs,
const char* name,
const uint8_t* bytes,
uint32_t count);
void fieldset_add_float(
ProtoViewFieldSet* fs,
const char* name,
float val,
uint32_t digits_after_dot);
const char* field_get_type_name(ProtoViewField* f);
int field_to_string(char* buf, size_t len, ProtoViewField* f);
bool field_set_from_string(ProtoViewField* f, char* buf, size_t len);
bool field_incr_value(ProtoViewField* f, int incr);
void fieldset_copy_matching_fields(ProtoViewFieldSet* dst, ProtoViewFieldSet* src);
void field_set_from_field(ProtoViewField* dst, ProtoViewField* src);
/* crc.c */
uint8_t crc8(const uint8_t *data, size_t len, uint8_t init, uint8_t poly);
uint8_t crc8(const uint8_t* data, size_t len, uint8_t init, uint8_t poly);

68
applications/plugins/protoview/app_subghz.c
View File

@@ -9,18 +9,20 @@
#include <furi_hal_spi.h>
#include <furi_hal_interrupt.h>
void raw_sampling_worker_start(ProtoViewApp *app);
void raw_sampling_worker_stop(ProtoViewApp *app);
void raw_sampling_worker_start(ProtoViewApp* app);
void raw_sampling_worker_stop(ProtoViewApp* app);
ProtoViewModulation ProtoViewModulations[] = {
{"OOK 650Khz", "FuriHalSubGhzPresetOok650Async",
FuriHalSubGhzPresetOok650Async, NULL},
{"OOK 270Khz", "FuriHalSubGhzPresetOok270Async",
FuriHalSubGhzPresetOok270Async, NULL},
{"2FSK 2.38Khz", "FuriHalSubGhzPreset2FSKDev238Async",
FuriHalSubGhzPreset2FSKDev238Async, NULL},
{"2FSK 47.6Khz", "FuriHalSubGhzPreset2FSKDev476Async",
FuriHalSubGhzPreset2FSKDev476Async, NULL},
{"OOK 650Khz", "FuriHalSubGhzPresetOok650Async", FuriHalSubGhzPresetOok650Async, NULL},
{"OOK 270Khz", "FuriHalSubGhzPresetOok270Async", FuriHalSubGhzPresetOok270Async, NULL},
{"2FSK 2.38Khz",
"FuriHalSubGhzPreset2FSKDev238Async",
FuriHalSubGhzPreset2FSKDev238Async,
NULL},
{"2FSK 47.6Khz",
"FuriHalSubGhzPreset2FSKDev476Async",
FuriHalSubGhzPreset2FSKDev476Async,
NULL},
{"TPMS 1 (FSK)", NULL, 0, (uint8_t*)protoview_subghz_tpms1_fsk_async_regs},
{"TPMS 2 (OOK)", NULL, 0, (uint8_t*)protoview_subghz_tpms2_ook_async_regs},
{"TPMS 3 (FSK)", NULL, 0, (uint8_t*)protoview_subghz_tpms3_fsk_async_regs},
@@ -44,12 +46,10 @@ void radio_begin(ProtoViewApp* app) {
/* The CC1101 preset can be either one of the standard presets, if
* the modulation "custom" field is NULL, or a custom preset we
* defined in custom_presets.h. */
if (ProtoViewModulations[app->modulation].custom == NULL) {
furi_hal_subghz_load_preset(
ProtoViewModulations[app->modulation].preset);
if(ProtoViewModulations[app->modulation].custom == NULL) {
furi_hal_subghz_load_preset(ProtoViewModulations[app->modulation].preset);
} else {
furi_hal_subghz_load_custom_preset(
ProtoViewModulations[app->modulation].custom);
furi_hal_subghz_load_custom_preset(ProtoViewModulations[app->modulation].custom);
}
furi_hal_gpio_init(&gpio_cc1101_g0, GpioModeInput, GpioPullNo, GpioSpeedLow);
app->txrx->txrx_state = TxRxStateIDLE;
@@ -61,10 +61,10 @@ void radio_begin(ProtoViewApp* app) {
uint32_t radio_rx(ProtoViewApp* app) {
furi_assert(app);
if(!furi_hal_subghz_is_frequency_valid(app->frequency)) {
furi_crash(TAG" Incorrect RX frequency.");
furi_crash(TAG " Incorrect RX frequency.");
}
if (app->txrx->txrx_state == TxRxStateRx) return app->frequency;
if(app->txrx->txrx_state == TxRxStateRx) return app->frequency;
furi_hal_subghz_idle(); /* Put it into idle state in case it is sleeping. */
uint32_t value = furi_hal_subghz_set_frequency_and_path(app->frequency);
@@ -72,10 +72,8 @@ uint32_t radio_rx(ProtoViewApp* app) {
furi_hal_gpio_init(&gpio_cc1101_g0, GpioModeInput, GpioPullNo, GpioSpeedLow);
furi_hal_subghz_flush_rx();
furi_hal_subghz_rx();
if (!app->txrx->debug_timer_sampling) {
furi_hal_subghz_start_async_rx(subghz_worker_rx_callback,
app->txrx->worker);
if(!app->txrx->debug_timer_sampling) {
furi_hal_subghz_start_async_rx(subghz_worker_rx_callback, app->txrx->worker);
subghz_worker_start(app->txrx->worker);
} else {
raw_sampling_worker_start(app);
@@ -88,8 +86,8 @@ uint32_t radio_rx(ProtoViewApp* app) {
void radio_rx_end(ProtoViewApp* app) {
furi_assert(app);
if (app->txrx->txrx_state == TxRxStateRx) {
if (!app->txrx->debug_timer_sampling) {
if(app->txrx->txrx_state == TxRxStateRx) {
if(!app->txrx->debug_timer_sampling) {
if(subghz_worker_is_running(app->txrx->worker)) {
subghz_worker_stop(app->txrx->worker);
furi_hal_subghz_stop_async_rx();
@@ -105,7 +103,7 @@ void radio_rx_end(ProtoViewApp* app) {
/* Put radio on sleep. */
void radio_sleep(ProtoViewApp* app) {
furi_assert(app);
if (app->txrx->txrx_state == TxRxStateRx) {
if(app->txrx->txrx_state == TxRxStateRx) {
/* We can't go from having an active RX worker to sleeping.
* Stop the RX subsystems first. */
radio_rx_end(app);
@@ -120,10 +118,10 @@ void radio_sleep(ProtoViewApp* app) {
/* This function suspends the current RX state, switches to TX mode,
* transmits the signal provided by the callback data_feeder, and later
* restores the RX state if there was one. */
void radio_tx_signal(ProtoViewApp *app, FuriHalSubGhzAsyncTxCallback data_feeder, void *ctx) {
void radio_tx_signal(ProtoViewApp* app, FuriHalSubGhzAsyncTxCallback data_feeder, void* ctx) {
TxRxState oldstate = app->txrx->txrx_state;
if (oldstate == TxRxStateRx) radio_rx_end(app);
if(oldstate == TxRxStateRx) radio_rx_end(app);
radio_begin(app);
furi_hal_subghz_idle();
@@ -138,7 +136,7 @@ void radio_tx_signal(ProtoViewApp *app, FuriHalSubGhzAsyncTxCallback data_feeder
furi_hal_subghz_idle();
radio_begin(app);
if (oldstate == TxRxStateRx) radio_rx(app);
if(oldstate == TxRxStateRx) radio_rx(app);
}
/* ============================= Raw sampling mode =============================
@@ -148,15 +146,15 @@ void radio_tx_signal(ProtoViewApp *app, FuriHalSubGhzAsyncTxCallback data_feeder
* Flipper system.
* ===========================================================================*/
void protoview_timer_isr(void *ctx) {
ProtoViewApp *app = ctx;
void protoview_timer_isr(void* ctx) {
ProtoViewApp* app = ctx;
bool level = furi_hal_gpio_read(&gpio_cc1101_g0);
if (app->txrx->last_g0_value != level) {
if(app->txrx->last_g0_value != level) {
uint32_t now = DWT->CYCCNT;
uint32_t dur = now - app->txrx->last_g0_change_time;
dur /= furi_hal_cortex_instructions_per_microsecond();
if (dur > 15000) dur = 15000;
if(dur > 15000) dur = 15000;
raw_samples_add(RawSamples, app->txrx->last_g0_value, dur);
app->txrx->last_g0_value = level;
app->txrx->last_g0_change_time = now;
@@ -164,13 +162,13 @@ void protoview_timer_isr(void *ctx) {
LL_TIM_ClearFlag_UPDATE(TIM2);
}
void raw_sampling_worker_start(ProtoViewApp *app) {
void raw_sampling_worker_start(ProtoViewApp* app) {
UNUSED(app);
LL_TIM_InitTypeDef tim_init = {
.Prescaler = 63, /* CPU frequency is ~64Mhz. */
.Prescaler = 63, /* CPU frequency is ~64Mhz. */
.CounterMode = LL_TIM_COUNTERMODE_UP,
.Autoreload = 5, /* Sample every 5 us */
.Autoreload = 5, /* Sample every 5 us */
};
LL_TIM_Init(TIM2, &tim_init);
@@ -183,7 +181,7 @@ void raw_sampling_worker_start(ProtoViewApp *app) {
FURI_LOG_E(TAG, "Timer enabled");
}
void raw_sampling_worker_stop(ProtoViewApp *app) {
void raw_sampling_worker_stop(ProtoViewApp* app) {
UNUSED(app);
FURI_CRITICAL_ENTER();
LL_TIM_DisableCounter(TIM2);

9
applications/plugins/protoview/crc.c
View File

@@ -3,14 +3,13 @@
/* CRC8 with the specified initialization value 'init' and
* polynomial 'poly'. */
uint8_t crc8(const uint8_t *data, size_t len, uint8_t init, uint8_t poly)
{
uint8_t crc8(const uint8_t* data, size_t len, uint8_t init, uint8_t poly) {
uint8_t crc = init;
size_t i, j;
for (i = 0; i < len; i++) {
for(i = 0; i < len; i++) {
crc ^= data[i];
for (j = 0; j < 8; j++) {
if ((crc & 0x80) != 0)
for(j = 0; j < 8; j++) {
if((crc & 0x80) != 0)
crc = (uint8_t)((crc << 1) ^ poly);
else
crc <<= 1;

31
applications/plugins/protoview/custom_presets.h
View File

@@ -76,7 +76,8 @@ static uint8_t protoview_subghz_tpms1_fsk_async_regs[][2] = {
// // Modem Configuration
{CC1101_MDMCFG0, 0x00},
{CC1101_MDMCFG1, 0x02},
{CC1101_MDMCFG2, 0x04}, // Format 2-FSK/FM, No preamble/sync, Disable (current optimized). Other code reading TPMS uses GFSK, but should be the same when in RX mode.
{CC1101_MDMCFG2,
0x04}, // Format 2-FSK/FM, No preamble/sync, Disable (current optimized). Other code reading TPMS uses GFSK, but should be the same when in RX mode.
{CC1101_MDMCFG3, 0x93}, // Data rate is 20kBaud
{CC1101_MDMCFG4, 0x59}, // Rx bandwidth filter is 325 kHz
{CC1101_DEVIATN, 0x41}, // Deviation 28.56 kHz
@@ -106,8 +107,10 @@ static uint8_t protoview_subghz_tpms1_fsk_async_regs[][2] = {
{0, 0},
/* CC1101 2FSK PATABLE. */
{0xC0, 0}, {0,0}, {0,0}, {0,0}
};
{0xC0, 0},
{0, 0},
{0, 0},
{0, 0}};
/* This is like the default Flipper OOK 640Khz bandwidth preset, but
* the bandwidth is changed to 10kBaud to accomodate TPMS frequency. */
@@ -156,8 +159,10 @@ static const uint8_t protoview_subghz_tpms2_ook_async_regs[][2] = {
{0, 0},
/* CC1101 OOK PATABLE. */
{0, 0xC0}, {0,0}, {0,0}, {0,0}
};
{0, 0xC0},
{0, 0},
{0, 0},
{0, 0}};
/* 40 KBaud, 2FSK, 28 kHz deviation, 270 Khz bandwidth filter. */
static uint8_t protoview_subghz_tpms3_fsk_async_regs[][2] = {
@@ -174,7 +179,8 @@ static uint8_t protoview_subghz_tpms3_fsk_async_regs[][2] = {
// // Modem Configuration
{CC1101_MDMCFG0, 0x00},
{CC1101_MDMCFG1, 0x02},
{CC1101_MDMCFG2, 0x04}, // Format 2-FSK/FM, No preamble/sync, Disable (current optimized). Other code reading TPMS uses GFSK, but should be the same when in RX mode.
{CC1101_MDMCFG2,
0x04}, // Format 2-FSK/FM, No preamble/sync, Disable (current optimized). Other code reading TPMS uses GFSK, but should be the same when in RX mode.
{CC1101_MDMCFG3, 0x93}, // Data rate is 40kBaud
{CC1101_MDMCFG4, 0x6A}, // 6 = BW filter 270kHz, A = Data rate exp
{CC1101_DEVIATN, 0x41}, // Deviation 28kHz
@@ -204,8 +210,10 @@ static uint8_t protoview_subghz_tpms3_fsk_async_regs[][2] = {
{0, 0},
/* CC1101 2FSK PATABLE. */
{0xC0, 0}, {0,0}, {0,0}, {0,0}
};
{0xC0, 0},
{0, 0},
{0, 0},
{0, 0}};
/* FSK 19k dev, 325 Khz filter, 20kBaud. Works well with Toyota. */
static uint8_t protoview_subghz_tpms4_fsk_async_regs[][2] = {
@@ -250,6 +258,7 @@ static uint8_t protoview_subghz_tpms4_fsk_async_regs[][2] = {
{0, 0},
/* CC1101 2FSK PATABLE. */
{0xC0, 0}, {0,0}, {0,0}, {0,0}
};
{0xC0, 0},
{0, 0},
{0, 0},
{0, 0}};

17
applications/plugins/protoview/data_feed.c
View File

@@ -14,7 +14,7 @@ const SubGhzProtocol subghz_protocol_protoview;
/* The feed() method puts data in the RawSamples global (protected by
* a mutex). */
extern RawSamplesBuffer *RawSamples;
extern RawSamplesBuffer* RawSamples;
/* This is totally dummy: we just define the decoder base for the async
* system to work but we don't really use it if not to collect raw
@@ -26,8 +26,7 @@ typedef struct SubGhzProtocolDecoderprotoview {
void* subghz_protocol_decoder_protoview_alloc(SubGhzEnvironment* environment) {
UNUSED(environment);
SubGhzProtocolDecoderprotoview* instance =
malloc(sizeof(SubGhzProtocolDecoderprotoview));
SubGhzProtocolDecoderprotoview* instance = malloc(sizeof(SubGhzProtocolDecoderprotoview));
instance->base.protocol = &subghz_protocol_protoview;
return instance;
}
@@ -66,8 +65,7 @@ uint8_t subghz_protocol_decoder_protoview_get_hash_data(void* context) {
bool subghz_protocol_decoder_protoview_serialize(
void* context,
FlipperFormat* flipper_format,
SubGhzRadioPreset* preset)
{
SubGhzRadioPreset* preset) {
UNUSED(context);
UNUSED(flipper_format);
UNUSED(preset);
@@ -75,15 +73,13 @@ bool subghz_protocol_decoder_protoview_serialize(
}
/* Not used. */
bool subghz_protocol_decoder_protoview_deserialize(void* context, FlipperFormat* flipper_format)
{
bool subghz_protocol_decoder_protoview_deserialize(void* context, FlipperFormat* flipper_format) {
UNUSED(context);
UNUSED(flipper_format);
return false;
}
void subhz_protocol_decoder_protoview_get_string(void* context, FuriString* output)
{
void subhz_protocol_decoder_protoview_get_string(void* context, FuriString* output) {
furi_assert(context);
furi_string_cat_printf(output, "Protoview");
}
@@ -116,5 +112,4 @@ const SubGhzProtocol* protoview_protocol_registry_items[] = {
const SubGhzProtocolRegistry protoview_protocol_registry = {
.items = protoview_protocol_registry_items,
.size = COUNT_OF(protoview_protocol_registry_items)
};
.size = COUNT_OF(protoview_protocol_registry_items)};

348
applications/plugins/protoview/fields.c
View File

@@ -7,8 +7,8 @@
/* Create a new field of the specified type. Without populating its
* type-specific value. */
static ProtoViewField *field_new(ProtoViewFieldType type, const char *name) {
ProtoViewField *f = malloc(sizeof(*f));
static ProtoViewField* field_new(ProtoViewFieldType type, const char* name) {
ProtoViewField* f = malloc(sizeof(*f));
f->type = type;
f->name = strdup(name);
return f;
@@ -16,72 +16,80 @@ static ProtoViewField *field_new(ProtoViewFieldType type, const char *name) {
/* Free only the auxiliary data of a field, used to represent the
* current type. Name and type are not touched. */
static void field_free_aux_data(ProtoViewField *f) {
static void field_free_aux_data(ProtoViewField* f) {
switch(f->type) {
case FieldTypeStr: free(f->str); break;
case FieldTypeBytes: free(f->bytes); break;
default: break; // Nothing to free for other types.
case FieldTypeStr:
free(f->str);
break;
case FieldTypeBytes:
free(f->bytes);
break;
default:
break; // Nothing to free for other types.
}
}
/* Free a field an associated data. */
static void field_free(ProtoViewField *f) {
static void field_free(ProtoViewField* f) {
field_free_aux_data(f);
free(f->name);
free(f);
}
/* Return the type of the field as string. */
const char *field_get_type_name(ProtoViewField *f) {
const char* field_get_type_name(ProtoViewField* f) {
switch(f->type) {
case FieldTypeStr: return "str";
case FieldTypeSignedInt: return "int";
case FieldTypeUnsignedInt: return "uint";
case FieldTypeBinary: return "bin";
case FieldTypeHex: return "hex";
case FieldTypeBytes: return "bytes";
case FieldTypeFloat: return "float";
case FieldTypeStr:
return "str";
case FieldTypeSignedInt:
return "int";
case FieldTypeUnsignedInt:
return "uint";
case FieldTypeBinary:
return "bin";
case FieldTypeHex:
return "hex";
case FieldTypeBytes:
return "bytes";
case FieldTypeFloat:
return "float";
}
return "unknown";
}
/* Set a string representation of the specified field in buf. */
int field_to_string(char *buf, size_t len, ProtoViewField *f) {
int field_to_string(char* buf, size_t len, ProtoViewField* f) {
switch(f->type) {
case FieldTypeStr:
return snprintf(buf,len,"%s", f->str);
return snprintf(buf, len, "%s", f->str);
case FieldTypeSignedInt:
return snprintf(buf,len,"%lld", (long long) f->value);
return snprintf(buf, len, "%lld", (long long)f->value);
case FieldTypeUnsignedInt:
return snprintf(buf,len,"%llu", (unsigned long long) f->uvalue);
case FieldTypeBinary:
{
uint64_t test_bit = (1 << (f->len-1));
uint64_t idx = 0;
while(idx < len-1 && test_bit) {
buf[idx++] = (f->uvalue & test_bit) ? '1' : '0';
test_bit >>= 1;
}
buf[idx] = 0;
return idx;
return snprintf(buf, len, "%llu", (unsigned long long)f->uvalue);
case FieldTypeBinary: {
uint64_t test_bit = (1 << (f->len - 1));
uint64_t idx = 0;
while(idx < len - 1 && test_bit) {
buf[idx++] = (f->uvalue & test_bit) ? '1' : '0';
test_bit >>= 1;
}
buf[idx] = 0;
return idx;
}
case FieldTypeHex:
return snprintf(buf, len, "%*llX", (int)(f->len+7)/8, f->uvalue);
return snprintf(buf, len, "%*llX", (int)(f->len + 7) / 8, f->uvalue);
case FieldTypeFloat:
return snprintf(buf, len, "%.*f", (int)f->len, (double)f->fvalue);
case FieldTypeBytes:
{
uint64_t idx = 0;
while(idx < len-1 && idx < f->len) {
const char *charset = "0123456789ABCDEF";
uint32_t nibble = idx & 1 ?
(f->bytes[idx/2] & 0xf) :
(f->bytes[idx/2] >> 4);
buf[idx++] = charset[nibble];
}
buf[idx] = 0;
return idx;
case FieldTypeBytes: {
uint64_t idx = 0;
while(idx < len - 1 && idx < f->len) {
const char* charset = "0123456789ABCDEF";
uint32_t nibble = idx & 1 ? (f->bytes[idx / 2] & 0xf) : (f->bytes[idx / 2] >> 4);
buf[idx++] = charset[nibble];
}
buf[idx] = 0;
return idx;
}
}
return 0;
}
@@ -96,7 +104,7 @@ int field_to_string(char *buf, size_t len, ProtoViewField *f) {
* The function returns true if the filed was successfully set to the
* new value, otherwise if the specified value is invalid for the
* field type, false is returned. */
bool field_set_from_string(ProtoViewField *f, char *buf, size_t len) {
bool field_set_from_string(ProtoViewField* f, char* buf, size_t len) {
// Initialize values to zero since the Flipper sscanf() implementation
// is fuzzy... may populate only part of the value.
long long val = 0;
@@ -107,80 +115,78 @@ bool field_set_from_string(ProtoViewField *f, char *buf, size_t len) {
case FieldTypeStr:
free(f->str);
f->len = len;
f->str = malloc(len+1);
memcpy(f->str,buf,len+1);
f->str = malloc(len + 1);
memcpy(f->str, buf, len + 1);
break;
case FieldTypeSignedInt:
if (!sscanf(buf,"%lld",&val)) return false;
if(!sscanf(buf, "%lld", &val)) return false;
f->value = val;
break;
case FieldTypeUnsignedInt:
if (!sscanf(buf,"%llu",&uval)) return false;
if(!sscanf(buf, "%llu", &uval)) return false;
f->uvalue = uval;
break;
case FieldTypeBinary:
{
uint64_t bit_to_set = (1 << (len-1));
uint64_t idx = 0;
uval = 0;
while(buf[idx]) {
if (buf[idx] == '1') uval |= bit_to_set;
else if (buf[idx] != '0') return false;
bit_to_set >>= 1;
idx++;
}
f->uvalue = uval;
case FieldTypeBinary: {
uint64_t bit_to_set = (1 << (len - 1));
uint64_t idx = 0;
uval = 0;
while(buf[idx]) {
if(buf[idx] == '1')
uval |= bit_to_set;
else if(buf[idx] != '0')
return false;
bit_to_set >>= 1;
idx++;
}
break;
f->uvalue = uval;
} break;
case FieldTypeHex:
if (!sscanf(buf,"%llx",&uval) &&
!sscanf(buf,"%llX",&uval)) return false;
if(!sscanf(buf, "%llx", &uval) && !sscanf(buf, "%llX", &uval)) return false;
f->uvalue = uval;
break;
case FieldTypeFloat:
if (!sscanf(buf,"%f",&fval)) return false;
if(!sscanf(buf, "%f", &fval)) return false;
f->fvalue = fval;
break;
case FieldTypeBytes:
{
if (len > f->len) return false;
uint64_t idx = 0;
while(buf[idx]) {
uint8_t nibble = 0;
char c = toupper(buf[idx]);
if (c >= '0' && c <= '9') nibble = c-'0';
else if (c >= 'A' && c <= 'F') nibble = 10+(c-'A');
else return false;
case FieldTypeBytes: {
if(len > f->len) return false;
uint64_t idx = 0;
while(buf[idx]) {
uint8_t nibble = 0;
char c = toupper(buf[idx]);
if(c >= '0' && c <= '9')
nibble = c - '0';
else if(c >= 'A' && c <= 'F')
nibble = 10 + (c - 'A');
else
return false;
if (idx & 1) {
f->bytes[idx/2] =
(f->bytes[idx/2] & 0xF0) | nibble;
} else {
f->bytes[idx/2] =
(f->bytes[idx/2] & 0x0F) | (nibble<<4);
}
idx++;
if(idx & 1) {
f->bytes[idx / 2] = (f->bytes[idx / 2] & 0xF0) | nibble;
} else {
f->bytes[idx / 2] = (f->bytes[idx / 2] & 0x0F) | (nibble << 4);
}
buf[idx] = 0;
idx++;
}
break;
buf[idx] = 0;
} break;
}
return true;
}
/* Set the 'dst' field to contain a copy of the value of the 'src'
* field. The field name is not modified. */
void field_set_from_field(ProtoViewField *dst, ProtoViewField *src) {
void field_set_from_field(ProtoViewField* dst, ProtoViewField* src) {
field_free_aux_data(dst);
dst->type = src->type;
dst->len = src->len;
switch(src->type) {
switch(src->type) {
case FieldTypeStr:
dst->str = strdup(src->str);
break;
case FieldTypeBytes:
dst->bytes = malloc(src->len);
memcpy(dst->bytes,src->bytes,dst->len);
memcpy(dst->bytes, src->bytes, dst->len);
break;
case FieldTypeSignedInt:
dst->value = src->value;
@@ -199,159 +205,159 @@ void field_set_from_field(ProtoViewField *dst, ProtoViewField *src) {
/* Increment the specified field value of 'incr'. If the field type
* does not support increments false is returned, otherwise the
* action is performed. */
bool field_incr_value(ProtoViewField *f, int incr) {
bool field_incr_value(ProtoViewField* f, int incr) {
switch(f->type) {
case FieldTypeStr: return false;
case FieldTypeSignedInt: {
/* Wrap around depending on the number of bits (f->len)
case FieldTypeStr:
return false;
case FieldTypeSignedInt: {
/* Wrap around depending on the number of bits (f->len)
* the integer was declared to have. */
int64_t max = (1ULL << (f->len-1))-1;
int64_t min = -max-1;
int64_t v = (int64_t)f->value + incr;
if (v > max) v = min+(v-max-1);
if (v < min) v = max+(v-min+1);
f->value = v;
break;
}
case FieldTypeBinary:
case FieldTypeHex:
case FieldTypeUnsignedInt: {
/* Wrap around like for the unsigned case, but here
int64_t max = (1ULL << (f->len - 1)) - 1;
int64_t min = -max - 1;
int64_t v = (int64_t)f->value + incr;
if(v > max) v = min + (v - max - 1);
if(v < min) v = max + (v - min + 1);
f->value = v;
break;
}
case FieldTypeBinary:
case FieldTypeHex:
case FieldTypeUnsignedInt: {
/* Wrap around like for the unsigned case, but here
* is simpler. */
uint64_t max = (1ULL << f->len)-1; // Broken for 64 bits.
uint64_t uv = (uint64_t)f->value + incr;
if (uv > max) uv = uv & max;
f->uvalue = uv;
break;
}
case FieldTypeFloat:
f->fvalue += incr;
break;
case FieldTypeBytes: {
// For bytes we only support single unit increments.
if (incr != -1 && incr != 1) return false;
for (int j = f->len-1; j >= 0; j--) {
uint8_t nibble = (j&1) ? (f->bytes[j/2] & 0x0F) :
((f->bytes[j/2] & 0xF0) >> 4);
uint64_t max = (1ULL << f->len) - 1; // Broken for 64 bits.
uint64_t uv = (uint64_t)f->value + incr;
if(uv > max) uv = uv & max;
f->uvalue = uv;
break;
}
case FieldTypeFloat:
f->fvalue += incr;
break;
case FieldTypeBytes: {
// For bytes we only support single unit increments.
if(incr != -1 && incr != 1) return false;
for(int j = f->len - 1; j >= 0; j--) {
uint8_t nibble = (j & 1) ? (f->bytes[j / 2] & 0x0F) : ((f->bytes[j / 2] & 0xF0) >> 4);
nibble += incr;
nibble &= 0x0F;
nibble += incr;
nibble &= 0x0F;
f->bytes[j/2] = (j&1) ? ((f->bytes[j/2] & 0xF0) | nibble) :
((f->bytes[j/2] & 0x0F) | (nibble<<4));
f->bytes[j / 2] = (j & 1) ? ((f->bytes[j / 2] & 0xF0) | nibble) :
((f->bytes[j / 2] & 0x0F) | (nibble << 4));
/* Propagate the operation on overflow of this nibble. */
if ((incr == 1 && nibble == 0) ||
(incr == -1 && nibble == 0xf))
{
continue;
}
break; // Otherwise stop the loop here.
/* Propagate the operation on overflow of this nibble. */
if((incr == 1 && nibble == 0) || (incr == -1 && nibble == 0xf)) {
continue;
}
break;
break; // Otherwise stop the loop here.
}
break;
}
}
return true;
}
/* Free a field set and its contained fields. */
void fieldset_free(ProtoViewFieldSet *fs) {
for (uint32_t j = 0; j < fs->numfields; j++)
field_free(fs->fields[j]);
void fieldset_free(ProtoViewFieldSet* fs) {
for(uint32_t j = 0; j < fs->numfields; j++) field_free(fs->fields[j]);
free(fs->fields);
free(fs);
}
/* Allocate and init an empty field set. */
ProtoViewFieldSet *fieldset_new(void) {
ProtoViewFieldSet *fs = malloc(sizeof(*fs));
ProtoViewFieldSet* fieldset_new(void) {
ProtoViewFieldSet* fs = malloc(sizeof(*fs));
fs->numfields = 0;
fs->fields = NULL;
return fs;
}
/* Append an already allocated field at the end of the specified field set. */
static void fieldset_add_field(ProtoViewFieldSet *fs, ProtoViewField *field) {
static void fieldset_add_field(ProtoViewFieldSet* fs, ProtoViewField* field) {
fs->numfields++;
fs->fields = realloc(fs->fields,sizeof(ProtoViewField*)*fs->numfields);
fs->fields[fs->numfields-1] = field;
fs->fields = realloc(fs->fields, sizeof(ProtoViewField*) * fs->numfields);
fs->fields[fs->numfields - 1] = field;
}
/* Allocate and append an integer field. */
void fieldset_add_int(ProtoViewFieldSet *fs, const char *name, int64_t val, uint8_t bits) {
ProtoViewField *f = field_new(FieldTypeSignedInt,name);
void fieldset_add_int(ProtoViewFieldSet* fs, const char* name, int64_t val, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeSignedInt, name);
f->value = val;
f->len = bits;
fieldset_add_field(fs,f);
fieldset_add_field(fs, f);
}
/* Allocate and append an unsigned field. */
void fieldset_add_uint(ProtoViewFieldSet *fs, const char *name, uint64_t uval, uint8_t bits) {
ProtoViewField *f = field_new(FieldTypeUnsignedInt,name);
void fieldset_add_uint(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeUnsignedInt, name);
f->uvalue = uval;
f->len = bits;
fieldset_add_field(fs,f);
fieldset_add_field(fs, f);
}
/* Allocate and append a hex field. This is an unsigned number but
* with an hex representation. */
void fieldset_add_hex(ProtoViewFieldSet *fs, const char *name, uint64_t uval, uint8_t bits) {
ProtoViewField *f = field_new(FieldTypeHex,name);
void fieldset_add_hex(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeHex, name);
f->uvalue = uval;
f->len = bits;
fieldset_add_field(fs,f);
fieldset_add_field(fs, f);
}
/* Allocate and append a bin field. This is an unsigned number but
* with a binary representation. */
void fieldset_add_bin(ProtoViewFieldSet *fs, const char *name, uint64_t uval, uint8_t bits) {
ProtoViewField *f = field_new(FieldTypeBinary,name);
void fieldset_add_bin(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeBinary, name);
f->uvalue = uval;
f->len = bits;
fieldset_add_field(fs,f);
fieldset_add_field(fs, f);
}
/* Allocate and append a string field. */
void fieldset_add_str(ProtoViewFieldSet *fs, const char *name, const char *s) {
ProtoViewField *f = field_new(FieldTypeStr,name);
void fieldset_add_str(ProtoViewFieldSet* fs, const char* name, const char* s) {
ProtoViewField* f = field_new(FieldTypeStr, name);
f->str = strdup(s);
f->len = strlen(s);
fieldset_add_field(fs,f);
fieldset_add_field(fs, f);
}
/* Allocate and append a bytes field. Note that 'count' is specified in
* nibbles (bytes*2). */
void fieldset_add_bytes(ProtoViewFieldSet *fs, const char *name, const uint8_t *bytes, uint32_t count_nibbles) {
uint32_t numbytes = (count_nibbles+count_nibbles%2)/2;
ProtoViewField *f = field_new(FieldTypeBytes,name);
void fieldset_add_bytes(
ProtoViewFieldSet* fs,
const char* name,
const uint8_t* bytes,
uint32_t count_nibbles) {
uint32_t numbytes = (count_nibbles + count_nibbles % 2) / 2;
ProtoViewField* f = field_new(FieldTypeBytes, name);
f->bytes = malloc(numbytes);
memcpy(f->bytes,bytes,numbytes);
memcpy(f->bytes, bytes, numbytes);
f->len = count_nibbles;
fieldset_add_field(fs,f);
fieldset_add_field(fs, f);
}
/* Allocate and append a float field. */
void fieldset_add_float(ProtoViewFieldSet *fs, const char *name, float val, uint32_t digits_after_dot) {
ProtoViewField *f = field_new(FieldTypeFloat,name);
void fieldset_add_float(
ProtoViewFieldSet* fs,
const char* name,
float val,
uint32_t digits_after_dot) {
ProtoViewField* f = field_new(FieldTypeFloat, name);
f->fvalue = val;
f->len = digits_after_dot;
fieldset_add_field(fs,f);
fieldset_add_field(fs, f);
}
/* For each field of the destination filedset 'dst', look for a matching
* field name/type in the source fieldset 'src', and if one is found copy
* its value into the 'dst' field. */
void fieldset_copy_matching_fields(ProtoViewFieldSet *dst,
ProtoViewFieldSet *src)
{
for (uint32_t j = 0; j < dst->numfields; j++) {
for (uint32_t i = 0; i < src->numfields; i++) {
if (dst->fields[j]->type == src->fields[i]->type &&
!strcmp(dst->fields[j]->name,src->fields[i]->name))
{
field_set_from_field(dst->fields[j],
src->fields[i]);
void fieldset_copy_matching_fields(ProtoViewFieldSet* dst, ProtoViewFieldSet* src) {
for(uint32_t j = 0; j < dst->numfields; j++) {
for(uint32_t i = 0; i < src->numfields; i++) {
if(dst->fields[j]->type == src->fields[i]->type &&
!strcmp(dst->fields[j]->name, src->fields[i]->name)) {
field_set_from_field(dst->fields[j], src->fields[i]);
}
}
}

67
applications/plugins/protoview/protocols/b4b1.c
View File

@@ -9,9 +9,9 @@
#include "../app.h"
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
if (numbits < 30) return false;
const char *sync_patterns[3] = {
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
if(numbits < 30) return false;
const char* sync_patterns[3] = {
"10000000000000000000000000000001", /* 30 zero bits. */
"100000000000000000000000000000001", /* 31 zero bits. */
"1000000000000000000000000000000001", /* 32 zero bits. */
@@ -19,70 +19,67 @@ static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoView
uint32_t off;
int j;
for (j = 0; j < 3; j++) {
off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_patterns[j]);
if (off != BITMAP_SEEK_NOT_FOUND) break;
for(j = 0; j < 3; j++) {
off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_patterns[j]);
if(off != BITMAP_SEEK_NOT_FOUND) break;
}
if (off == BITMAP_SEEK_NOT_FOUND) return false;
if (DEBUG_MSG) FURI_LOG_E(TAG, "B4B1 preamble at: %lu",off);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
if(DEBUG_MSG) FURI_LOG_E(TAG, "B4B1 preamble at: %lu", off);
info->start_off = off;
// Seek data setction. Why -1? Last bit is data.
off += strlen(sync_patterns[j])-1;
off += strlen(sync_patterns[j]) - 1;
uint8_t d[3]; /* 24 bits of data. */
uint32_t decoded =
convert_from_line_code(d,sizeof(d),bits,numbytes,off,"1000","1110");
uint32_t decoded = convert_from_line_code(d, sizeof(d), bits, numbytes, off, "1000", "1110");
if (DEBUG_MSG) FURI_LOG_E(TAG, "B4B1 decoded: %lu",decoded);
if (decoded < 24) return false;
if(DEBUG_MSG) FURI_LOG_E(TAG, "B4B1 decoded: %lu", decoded);
if(decoded < 24) return false;
off += 24*4; // seek to end symbol offset to calculate the length.
off += 24 * 4; // seek to end symbol offset to calculate the length.
off++; // In this protocol there is a final pulse as terminator.
info->pulses_count = off - info->start_off;
fieldset_add_bytes(info->fieldset,"id",d,5);
fieldset_add_uint(info->fieldset,"button",d[2]&0xf,4);
fieldset_add_bytes(info->fieldset, "id", d, 5);
fieldset_add_uint(info->fieldset, "button", d[2] & 0xf, 4);
return true;
}
/* Give fields and defaults for the signal creator. */
static void get_fields(ProtoViewFieldSet *fieldset) {
uint8_t default_id[3]= {0xAB, 0xCD, 0xE0};
fieldset_add_bytes(fieldset,"id",default_id,5);
fieldset_add_uint(fieldset,"button",1,4);
static void get_fields(ProtoViewFieldSet* fieldset) {
uint8_t default_id[3] = {0xAB, 0xCD, 0xE0};
fieldset_add_bytes(fieldset, "id", default_id, 5);
fieldset_add_uint(fieldset, "button", 1, 4);
}
/* Create a signal. */
static void build_message(RawSamplesBuffer *samples, ProtoViewFieldSet *fs)
{
static void build_message(RawSamplesBuffer* samples, ProtoViewFieldSet* fs) {
uint32_t te = 334; // Short pulse duration in microseconds.
// Sync: 1 te pulse, 31 te gap.
raw_samples_add(samples,true,te);
raw_samples_add(samples,false,te*31);
raw_samples_add(samples, true, te);
raw_samples_add(samples, false, te * 31);
// ID + button state
uint8_t data[3];
memcpy(data,fs->fields[0]->bytes,3);
data[2] = (data[2]&0xF0) | (fs->fields[1]->uvalue & 0xF);
for (uint32_t j = 0; j < 24; j++) {
if (bitmap_get(data,sizeof(data),j)) {
raw_samples_add(samples,true,te*3);
raw_samples_add(samples,false,te);
memcpy(data, fs->fields[0]->bytes, 3);
data[2] = (data[2] & 0xF0) | (fs->fields[1]->uvalue & 0xF);
for(uint32_t j = 0; j < 24; j++) {
if(bitmap_get(data, sizeof(data), j)) {
raw_samples_add(samples, true, te * 3);
raw_samples_add(samples, false, te);
} else {
raw_samples_add(samples,true,te);
raw_samples_add(samples,false,te*3);
raw_samples_add(samples, true, te);
raw_samples_add(samples, false, te * 3);
}
}
// Signal terminator. Just a single short pulse.
raw_samples_add(samples,true,te);
raw_samples_add(samples, true, te);
}
ProtoViewDecoder B4B1Decoder = {
.name = "PT/SC remote",
.decode = decode,
.get_fields = get_fields,
.build_message = build_message
};
.build_message = build_message};

99
applications/plugins/protoview/protocols/keeloq.c
View File

@@ -24,16 +24,16 @@
#include "../app.h"
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
/* In the sync pattern, we require the 12 high/low pulses and at least
* half the gap we expect (5 pulses times, one is the final zero in the
* 24 symbols high/low sequence, then other 4). */
const char *sync_pattern = "101010101010101010101010" "0000";
uint8_t sync_len = 24+4;
if (numbits-sync_len+sync_len < 3*66) return false;
uint32_t off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_pattern);
if (off == BITMAP_SEEK_NOT_FOUND) return false;
const char* sync_pattern = "101010101010101010101010"
"0000";
uint8_t sync_len = 24 + 4;
if(numbits - sync_len + sync_len < 3 * 66) return false;
uint32_t off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_pattern);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
info->start_off = off;
off += sync_len; // Seek start of message.
@@ -42,84 +42,77 @@ static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoView
* symbols of gap, to avoid missing the signal for a matter of wrong
* timing. */
uint8_t gap_len = 0;
while(gap_len <= 7 && bitmap_get(bits,numbytes,off+gap_len) == 0)
gap_len++;
if (gap_len < 3 || gap_len > 7) return false;
while(gap_len <= 7 && bitmap_get(bits, numbytes, off + gap_len) == 0) gap_len++;
if(gap_len < 3 || gap_len > 7) return false;
off += gap_len;
FURI_LOG_E(TAG, "Keeloq preamble+sync found");
uint8_t raw[9] = {0};
uint32_t decoded =
convert_from_line_code(raw,sizeof(raw),bits,numbytes,off,
"110","100"); /* Pulse width modulation. */
uint32_t decoded = convert_from_line_code(
raw, sizeof(raw), bits, numbytes, off, "110", "100"); /* Pulse width modulation. */
FURI_LOG_E(TAG, "Keeloq decoded bits: %lu", decoded);
if (decoded < 66) return false; /* Require the full 66 bits. */
if(decoded < 66) return false; /* Require the full 66 bits. */
info->pulses_count = (off+66*3) - info->start_off;
info->pulses_count = (off + 66 * 3) - info->start_off;
bitmap_reverse_bytes_bits(raw,sizeof(raw)); /* Keeloq is LSB first. */
bitmap_reverse_bytes_bits(raw, sizeof(raw)); /* Keeloq is LSB first. */
int buttons = raw[7]>>4;
int lowbat = (raw[8]&0x1) == 0; // Actual bit meaning: good battery level
int alwaysone = (raw[8]&0x2) != 0;
int buttons = raw[7] >> 4;
int lowbat = (raw[8] & 0x1) == 0; // Actual bit meaning: good battery level
int alwaysone = (raw[8] & 0x2) != 0;
fieldset_add_bytes(info->fieldset,"encr",raw,8);
raw[7] = raw[7]<<4; // Make ID bits contiguous
fieldset_add_bytes(info->fieldset,"id",raw+4,7); // 28 bits, 7 nibbles
fieldset_add_bin(info->fieldset,"s[2,1,0,3]",buttons,4);
fieldset_add_bin(info->fieldset,"low battery",lowbat,1);
fieldset_add_bin(info->fieldset,"always one",alwaysone,1);
fieldset_add_bytes(info->fieldset, "encr", raw, 8);
raw[7] = raw[7] << 4; // Make ID bits contiguous
fieldset_add_bytes(info->fieldset, "id", raw + 4, 7); // 28 bits, 7 nibbles
fieldset_add_bin(info->fieldset, "s[2,1,0,3]", buttons, 4);
fieldset_add_bin(info->fieldset, "low battery", lowbat, 1);
fieldset_add_bin(info->fieldset, "always one", alwaysone, 1);
return true;
}
static void get_fields(ProtoViewFieldSet *fieldset) {
static void get_fields(ProtoViewFieldSet* fieldset) {
uint8_t remote_id[4] = {0xab, 0xcd, 0xef, 0xa0};
uint8_t encr[4] = {0xab, 0xab, 0xab, 0xab};
fieldset_add_bytes(fieldset,"encr",encr,8);
fieldset_add_bytes(fieldset,"id",remote_id,7);
fieldset_add_bin(fieldset,"s[2,1,0,3]",2,4);
fieldset_add_bin(fieldset,"low battery",0,1);
fieldset_add_bin(fieldset,"always one",1,1);
fieldset_add_bytes(fieldset, "encr", encr, 8);
fieldset_add_bytes(fieldset, "id", remote_id, 7);
fieldset_add_bin(fieldset, "s[2,1,0,3]", 2, 4);
fieldset_add_bin(fieldset, "low battery", 0, 1);
fieldset_add_bin(fieldset, "always one", 1, 1);
}
static void build_message(RawSamplesBuffer *samples, ProtoViewFieldSet *fieldset)
{
static void build_message(RawSamplesBuffer* samples, ProtoViewFieldSet* fieldset) {
uint32_t te = 380; // Short pulse duration in microseconds.
// Sync: 12 pairs of pulse/gap + 9 times gap
for (int j = 0; j < 12; j++) {
raw_samples_add(samples,true,te);
raw_samples_add(samples,false,te);
for(int j = 0; j < 12; j++) {
raw_samples_add(samples, true, te);
raw_samples_add(samples, false, te);
}
raw_samples_add(samples,false,te*9);
raw_samples_add(samples, false, te * 9);
// Data, 66 bits.
uint8_t data[9] = {0};
memcpy(data,fieldset->fields[0]->bytes,4); // Encrypted part.
memcpy(data+4,fieldset->fields[1]->bytes,4); // ID.
data[7] = data[7]>>4 | fieldset->fields[2]->uvalue << 4; // s[2,1,0,3]
memcpy(data, fieldset->fields[0]->bytes, 4); // Encrypted part.
memcpy(data + 4, fieldset->fields[1]->bytes, 4); // ID.
data[7] = data[7] >> 4 | fieldset->fields[2]->uvalue << 4; // s[2,1,0,3]
int low_battery = fieldset->fields[3] != 0;
int always_one = fieldset->fields[4] != 0;
low_battery = !low_battery; // Bit real meaning is good battery level.
data[8] |= low_battery;
data[8] |= (always_one << 1);
bitmap_reverse_bytes_bits(data,sizeof(data)); /* Keeloq is LSB first. */
bitmap_reverse_bytes_bits(data, sizeof(data)); /* Keeloq is LSB first. */
for (int j = 0; j < 66; j++) {
if (bitmap_get(data,9,j)) {
raw_samples_add(samples,true,te);
raw_samples_add(samples,false,te*2);
for(int j = 0; j < 66; j++) {
if(bitmap_get(data, 9, j)) {
raw_samples_add(samples, true, te);
raw_samples_add(samples, false, te * 2);
} else {
raw_samples_add(samples,true,te*2);
raw_samples_add(samples,false,te);
raw_samples_add(samples, true, te * 2);
raw_samples_add(samples, false, te);
}
}
}
ProtoViewDecoder KeeloqDecoder = {
.name = "Keeloq",
.decode = decode,
.get_fields = get_fields,
.build_message = build_message
};
ProtoViewDecoder KeeloqDecoder =
{.name = "Keeloq", .decode = decode, .get_fields = get_fields, .build_message = build_message};

90
applications/plugins/protoview/protocols/oregon2.c
View File

@@ -6,11 +6,14 @@
#include "../app.h"
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
if (numbits < 32) return false;
const char *sync_pattern = "01100110" "01100110" "10010110" "10010110";
uint64_t off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_pattern);
if (off == BITMAP_SEEK_NOT_FOUND) return false;
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
if(numbits < 32) return false;
const char* sync_pattern = "01100110"
"01100110"
"10010110"
"10010110";
uint64_t off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_pattern);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
FURI_LOG_E(TAG, "Oregon2 preamble+sync found");
info->start_off = off;
@@ -18,50 +21,61 @@ static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoView
uint8_t buffer[8], raw[8] = {0};
uint32_t decoded =
convert_from_line_code(buffer,sizeof(buffer),bits,numbytes,off,"1001","0110");
convert_from_line_code(buffer, sizeof(buffer), bits, numbytes, off, "1001", "0110");
FURI_LOG_E(TAG, "Oregon2 decoded bits: %lu", decoded);
if (decoded < 11*4) return false; /* Minimum len to extract some data. */
info->pulses_count = (off+11*4*4) - info->start_off;
if(decoded < 11 * 4) return false; /* Minimum len to extract some data. */
info->pulses_count = (off + 11 * 4 * 4) - info->start_off;
char temp[3] = {0}, hum[2] = {0};
uint8_t deviceid[2];
for (int j = 0; j < 64; j += 4) {
for(int j = 0; j < 64; j += 4) {
uint8_t nib[1];
nib[0] = (bitmap_get(buffer,8,j+0) |
bitmap_get(buffer,8,j+1) << 1 |
bitmap_get(buffer,8,j+2) << 2 |
bitmap_get(buffer,8,j+3) << 3);
if (DEBUG_MSG) FURI_LOG_E(TAG, "Not inverted nibble[%d]: %x", j/4, (unsigned int)nib[0]);
raw[j/8] |= nib[0] << (4-(j%4));
switch(j/4) {
case 1: deviceid[0] |= nib[0]; break;
case 0: deviceid[0] |= nib[0] << 4; break;
case 3: deviceid[1] |= nib[0]; break;
case 2: deviceid[1] |= nib[0] << 4; break;
case 10: temp[0] = nib[0]; break;
nib[0] =
(bitmap_get(buffer, 8, j + 0) | bitmap_get(buffer, 8, j + 1) << 1 |
bitmap_get(buffer, 8, j + 2) << 2 | bitmap_get(buffer, 8, j + 3) << 3);
if(DEBUG_MSG) FURI_LOG_E(TAG, "Not inverted nibble[%d]: %x", j / 4, (unsigned int)nib[0]);
raw[j / 8] |= nib[0] << (4 - (j % 4));
switch(j / 4) {
case 1:
deviceid[0] |= nib[0];
break;
case 0:
deviceid[0] |= nib[0] << 4;
break;
case 3:
deviceid[1] |= nib[0];
break;
case 2:
deviceid[1] |= nib[0] << 4;
break;
case 10:
temp[0] = nib[0];
break;
/* Fixme: take the temperature sign from nibble 11. */
case 9: temp[1] = nib[0]; break;
case 8: temp[2] = nib[0]; break;
case 13: hum[0] = nib[0]; break;
case 12: hum[1] = nib[0]; break;
case 9:
temp[1] = nib[0];
break;
case 8:
temp[2] = nib[0];
break;
case 13:
hum[0] = nib[0];
break;
case 12:
hum[1] = nib[0];
break;
}
}
float tempval = ((temp[0]-'0')*10) +
(temp[1]-'0') +
((float)(temp[2]-'0')*0.1);
int humval = (hum[0]-'0')*10 + (hum[1]-'0');
float tempval = ((temp[0] - '0') * 10) + (temp[1] - '0') + ((float)(temp[2] - '0') * 0.1);
int humval = (hum[0] - '0') * 10 + (hum[1] - '0');
fieldset_add_bytes(info->fieldset,"Sensor ID",deviceid,4);
fieldset_add_float(info->fieldset,"Temperature",tempval,1);
fieldset_add_uint(info->fieldset,"Humidity",humval,7);
fieldset_add_bytes(info->fieldset, "Sensor ID", deviceid, 4);
fieldset_add_float(info->fieldset, "Temperature", tempval, 1);
fieldset_add_uint(info->fieldset, "Humidity", humval, 7);
return true;
}
ProtoViewDecoder Oregon2Decoder = {
.name = "Oregon2",
.decode = decode,
.get_fields = NULL,
.build_message = NULL
};
ProtoViewDecoder Oregon2Decoder =
{.name = "Oregon2", .decode = decode, .get_fields = NULL, .build_message = NULL};

46
applications/plugins/protoview/protocols/tpms/citroen.c
View File

@@ -7,55 +7,49 @@
#include "../../app.h"
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
/* We consider a preamble of 17 symbols. They are more, but the decoding
* is more likely to happen if we don't pretend to receive from the
* very start of the message. */
uint32_t sync_len = 17;
const char *sync_pattern = "10101010101010110";
if (numbits-sync_len < 8*10) return false; /* Expect 10 bytes. */
const char* sync_pattern = "10101010101010110";
if(numbits - sync_len < 8 * 10) return false; /* Expect 10 bytes. */
uint64_t off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_pattern);
if (off == BITMAP_SEEK_NOT_FOUND) return false;
uint64_t off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_pattern);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
FURI_LOG_E(TAG, "Renault TPMS preamble+sync found");
info->start_off = off;
off += sync_len; /* Skip preamble + sync. */
uint8_t raw[10];
uint32_t decoded =
convert_from_line_code(raw,sizeof(raw),bits,numbytes,off,
"01","10"); /* Manchester. */
uint32_t decoded = convert_from_line_code(
raw, sizeof(raw), bits, numbytes, off, "01", "10"); /* Manchester. */
FURI_LOG_E(TAG, "Citroen TPMS decoded bits: %lu", decoded);
if (decoded < 8*10) return false; /* Require the full 10 bytes. */
if(decoded < 8 * 10) return false; /* Require the full 10 bytes. */
/* Check the CRC. It's a simple XOR of bytes 1-9, the first byte
* is not included. The meaning of the first byte is unknown and
* we don't display it. */
uint8_t crc = 0;
for (int j = 1; j < 10; j++) crc ^= raw[j];
if (crc != 0) return false; /* Require sane checksum. */
for(int j = 1; j < 10; j++) crc ^= raw[j];
if(crc != 0) return false; /* Require sane checksum. */
info->pulses_count = (off+8*10*2) - info->start_off;
info->pulses_count = (off + 8 * 10 * 2) - info->start_off;
int repeat = raw[5] & 0xf;
float kpa = (float)raw[6]*1.364;
int temp = raw[7]-50;
float kpa = (float)raw[6] * 1.364;
int temp = raw[7] - 50;
int battery = raw[8]; /* This may be the battery. It's not clear. */
fieldset_add_bytes(info->fieldset,"Tire ID",raw+1,4*2);
fieldset_add_float(info->fieldset,"Pressure kpa",kpa,2);
fieldset_add_int(info->fieldset,"Temperature C",temp,8);
fieldset_add_uint(info->fieldset,"Repeat",repeat,4);
fieldset_add_uint(info->fieldset,"Battery",battery,8);
fieldset_add_bytes(info->fieldset, "Tire ID", raw + 1, 4 * 2);
fieldset_add_float(info->fieldset, "Pressure kpa", kpa, 2);
fieldset_add_int(info->fieldset, "Temperature C", temp, 8);
fieldset_add_uint(info->fieldset, "Repeat", repeat, 4);
fieldset_add_uint(info->fieldset, "Battery", battery, 8);
return true;
}
ProtoViewDecoder CitroenTPMSDecoder = {
.name = "Citroen TPMS",
.decode = decode,
.get_fields = NULL,
.build_message = NULL
};
ProtoViewDecoder CitroenTPMSDecoder =
{.name = "Citroen TPMS", .decode = decode, .get_fields = NULL, .build_message = NULL};

49
applications/plugins/protoview/protocols/tpms/ford.c
View File

@@ -10,54 +10,49 @@
#include "../../app.h"
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
const char* sync_pattern = "010101010101"
"0110";
uint8_t sync_len = 12 + 4; /* We just use 12 preamble symbols + sync. */
if(numbits - sync_len < 8 * 8) return false;
const char *sync_pattern = "010101010101" "0110";
uint8_t sync_len = 12+4; /* We just use 12 preamble symbols + sync. */
if (numbits-sync_len < 8*8) return false;
uint64_t off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_pattern);
if (off == BITMAP_SEEK_NOT_FOUND) return false;
uint64_t off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_pattern);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
FURI_LOG_E(TAG, "Fort TPMS preamble+sync found");
info->start_off = off;
off += sync_len; /* Skip preamble and sync. */
uint8_t raw[8];
uint32_t decoded =
convert_from_line_code(raw,sizeof(raw),bits,numbytes,off,
"01","10"); /* Manchester. */
uint32_t decoded = convert_from_line_code(
raw, sizeof(raw), bits, numbytes, off, "01", "10"); /* Manchester. */
FURI_LOG_E(TAG, "Ford TPMS decoded bits: %lu", decoded);
if (decoded < 8*8) return false; /* Require the full 8 bytes. */
if(decoded < 8 * 8) return false; /* Require the full 8 bytes. */
/* CRC is just the sum of the first 7 bytes MOD 256. */
uint8_t crc = 0;
for (int j = 0; j < 7; j++) crc += raw[j];
if (crc != raw[7]) return false; /* Require sane CRC. */
for(int j = 0; j < 7; j++) crc += raw[j];
if(crc != raw[7]) return false; /* Require sane CRC. */
info->pulses_count = (off+8*8*2) - info->start_off;
info->pulses_count = (off + 8 * 8 * 2) - info->start_off;
float psi = 0.25 * (((raw[6]&0x20)<<3)|raw[4]);
float psi = 0.25 * (((raw[6] & 0x20) << 3) | raw[4]);
/* Temperature apperas to be valid only if the most significant
* bit of the value is not set. Otherwise its meaning is unknown.
* Likely useful to alternatively send temperature or other info. */
int temp = raw[5] & 0x80 ? 0 : raw[5]-56;
int temp = raw[5] & 0x80 ? 0 : raw[5] - 56;
int flags = raw[5] & 0x7f;
int car_moving = (raw[6] & 0x44) == 0x44;
fieldset_add_bytes(info->fieldset,"Tire ID",raw,4*2);
fieldset_add_float(info->fieldset,"Pressure psi",psi,2);
fieldset_add_int(info->fieldset,"Temperature C",temp,8);
fieldset_add_hex(info->fieldset,"Flags",flags,7);
fieldset_add_uint(info->fieldset,"Moving",car_moving,1);
fieldset_add_bytes(info->fieldset, "Tire ID", raw, 4 * 2);
fieldset_add_float(info->fieldset, "Pressure psi", psi, 2);
fieldset_add_int(info->fieldset, "Temperature C", temp, 8);
fieldset_add_hex(info->fieldset, "Flags", flags, 7);
fieldset_add_uint(info->fieldset, "Moving", car_moving, 1);
return true;
}
ProtoViewDecoder FordTPMSDecoder = {
.name = "Ford TPMS",
.decode = decode,
.get_fields = NULL,
.build_message = NULL
};
ProtoViewDecoder FordTPMSDecoder =
{.name = "Ford TPMS", .decode = decode, .get_fields = NULL, .build_message = NULL};

104
applications/plugins/protoview/protocols/tpms/renault.c
View File

@@ -6,85 +6,82 @@
#include "../../app.h"
#define USE_TEST_VECTOR 0
static const char *test_vector =
static const char* test_vector =
"...01010101010101010110" // Preamble + sync
/* The following is Marshal encoded, so each two characters are
* actaully one bit. 01 = 0, 10 = 1. */
"010110010110" // Flags.
"10011001101010011001" // Pressure, multiply by 0.75 to obtain kpa.
// 244 kpa here.
"1010010110011010" // Temperature, subtract 30 to obtain celsius. 22C here.
// 244 kpa here.
"1010010110011010" // Temperature, subtract 30 to obtain celsius. 22C here.
"1001010101101001"
"0101100110010101"
"1001010101100110" // Tire ID. 0x7AD779 here.
"1001010101100110" // Tire ID. 0x7AD779 here.
"0101010101010101"
"0101010101010101" // Two FF bytes (usually). Unknown.
"0101010101010101" // Two FF bytes (usually). Unknown.
"0110010101010101"; // CRC8 with (poly 7, initialization 0).
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
if (USE_TEST_VECTOR) { /* Test vector to check that decoding works. */
bitmap_set_pattern(bits,numbytes,0,test_vector);
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
if(USE_TEST_VECTOR) { /* Test vector to check that decoding works. */
bitmap_set_pattern(bits, numbytes, 0, test_vector);
numbits = strlen(test_vector);
}
if (numbits-12 < 9*8) return false;
if(numbits - 12 < 9 * 8) return false;
const char *sync_pattern = "01010101010101010110";
uint64_t off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_pattern);
if (off == BITMAP_SEEK_NOT_FOUND) return false;
const char* sync_pattern = "01010101010101010110";
uint64_t off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_pattern);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
FURI_LOG_E(TAG, "Renault TPMS preamble+sync found");
info->start_off = off;
off += 20; /* Skip preamble. */
uint8_t raw[9];
uint32_t decoded =
convert_from_line_code(raw,sizeof(raw),bits,numbytes,off,
"01","10"); /* Manchester. */
uint32_t decoded = convert_from_line_code(
raw, sizeof(raw), bits, numbytes, off, "01", "10"); /* Manchester. */
FURI_LOG_E(TAG, "Renault TPMS decoded bits: %lu", decoded);
if (decoded < 8*9) return false; /* Require the full 9 bytes. */
if (crc8(raw,8,0,7) != raw[8]) return false; /* Require sane CRC. */
if(decoded < 8 * 9) return false; /* Require the full 9 bytes. */
if(crc8(raw, 8, 0, 7) != raw[8]) return false; /* Require sane CRC. */
info->pulses_count = (off+8*9*2) - info->start_off;
info->pulses_count = (off + 8 * 9 * 2) - info->start_off;
uint8_t flags = raw[0]>>2;
float kpa = 0.75 * ((uint32_t)((raw[0]&3)<<8) | raw[1]);
int temp = raw[2]-30;
uint8_t flags = raw[0] >> 2;
float kpa = 0.75 * ((uint32_t)((raw[0] & 3) << 8) | raw[1]);
int temp = raw[2] - 30;
fieldset_add_bytes(info->fieldset,"Tire ID",raw+3,3*2);
fieldset_add_float(info->fieldset,"Pressure kpa",kpa,2);
fieldset_add_int(info->fieldset,"Temperature C",temp,8);
fieldset_add_hex(info->fieldset,"Flags",flags,6);
fieldset_add_bytes(info->fieldset,"Unknown1",raw+6,2);
fieldset_add_bytes(info->fieldset,"Unknown2",raw+7,2);
fieldset_add_bytes(info->fieldset, "Tire ID", raw + 3, 3 * 2);
fieldset_add_float(info->fieldset, "Pressure kpa", kpa, 2);
fieldset_add_int(info->fieldset, "Temperature C", temp, 8);
fieldset_add_hex(info->fieldset, "Flags", flags, 6);
fieldset_add_bytes(info->fieldset, "Unknown1", raw + 6, 2);
fieldset_add_bytes(info->fieldset, "Unknown2", raw + 7, 2);
return true;
}
/* Give fields and defaults for the signal creator. */
static void get_fields(ProtoViewFieldSet *fieldset) {
uint8_t default_id[3]= {0xAB, 0xCD, 0xEF};
fieldset_add_bytes(fieldset,"Tire ID",default_id,3*2);
fieldset_add_float(fieldset,"Pressure kpa",123,2);
fieldset_add_int(fieldset,"Temperature C",20,8);
static void get_fields(ProtoViewFieldSet* fieldset) {
uint8_t default_id[3] = {0xAB, 0xCD, 0xEF};
fieldset_add_bytes(fieldset, "Tire ID", default_id, 3 * 2);
fieldset_add_float(fieldset, "Pressure kpa", 123, 2);
fieldset_add_int(fieldset, "Temperature C", 20, 8);
// We don't know what flags are, but 1B is a common value.
fieldset_add_hex(fieldset,"Flags",0x1b,6);
fieldset_add_bytes(fieldset,"Unknown1",(uint8_t*)"\xff",2);
fieldset_add_bytes(fieldset,"Unknown2",(uint8_t*)"\xff",2);
fieldset_add_hex(fieldset, "Flags", 0x1b, 6);
fieldset_add_bytes(fieldset, "Unknown1", (uint8_t*)"\xff", 2);
fieldset_add_bytes(fieldset, "Unknown2", (uint8_t*)"\xff", 2);
}
/* Create a Renault TPMS signal, according to the fields provided. */
static void build_message(RawSamplesBuffer *samples, ProtoViewFieldSet *fieldset)
{
static void build_message(RawSamplesBuffer* samples, ProtoViewFieldSet* fieldset) {
uint32_t te = 50; // Short pulse duration in microseconds.
// Preamble + sync
const char *psync = "01010101010101010101010101010110";
const char *p = psync;
const char* psync = "01010101010101010101010101010110";
const char* p = psync;
while(*p) {
raw_samples_add_or_update(samples,*p == '1',te);
raw_samples_add_or_update(samples, *p == '1', te);
p++;
}
@@ -93,21 +90,21 @@ static void build_message(RawSamplesBuffer *samples, ProtoViewFieldSet *fieldset
unsigned int raw_pressure = fieldset->fields[1]->fvalue * 4 / 3;
data[0] = fieldset->fields[3]->uvalue << 2; // Flags
data[0] |= (raw_pressure >> 8) & 3; // Pressure kpa high 2 bits
data[1] = raw_pressure & 0xff; // Pressure kpa low 8 bits
data[1] = raw_pressure & 0xff; // Pressure kpa low 8 bits
data[2] = fieldset->fields[2]->value + 30; // Temperature C
memcpy(data+3,fieldset->fields[0]->bytes,6); // ID, 24 bits.
data[6] = fieldset->fields[4]->bytes[0]; // Unknown 1
data[7] = fieldset->fields[5]->bytes[0]; // Unknown 2
data[8] = crc8(data,8,0,7);
memcpy(data + 3, fieldset->fields[0]->bytes, 6); // ID, 24 bits.
data[6] = fieldset->fields[4]->bytes[0]; // Unknown 1
data[7] = fieldset->fields[5]->bytes[0]; // Unknown 2
data[8] = crc8(data, 8, 0, 7);
// Generate Manchester code for each bit
for (uint32_t j = 0; j < 9*8; j++) {
if (bitmap_get(data,sizeof(data),j)) {
raw_samples_add_or_update(samples,true,te);
raw_samples_add_or_update(samples,false,te);
for(uint32_t j = 0; j < 9 * 8; j++) {
if(bitmap_get(data, sizeof(data), j)) {
raw_samples_add_or_update(samples, true, te);
raw_samples_add_or_update(samples, false, te);
} else {
raw_samples_add_or_update(samples,false,te);
raw_samples_add_or_update(samples,true,te);
raw_samples_add_or_update(samples, false, te);
raw_samples_add_or_update(samples, true, te);
}
}
}
@@ -116,5 +113,4 @@ ProtoViewDecoder RenaultTPMSDecoder = {
.name = "Renault TPMS",
.decode = decode,
.get_fields = get_fields,
.build_message = build_message
};
.build_message = build_message};

52
applications/plugins/protoview/protocols/tpms/schrader.c
View File

@@ -11,20 +11,21 @@
#include "../../app.h"
#define USE_TEST_VECTOR 0
static const char *test_vector = "000000111101010101011010010110010110101001010110100110011001100101010101011010100110100110011010101010101010101010101010101010101010101010101010";
static const char* test_vector =
"000000111101010101011010010110010110101001010110100110011001100101010101011010100110100110011010101010101010101010101010101010101010101010101010";
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
if (USE_TEST_VECTOR) { /* Test vector to check that decoding works. */
bitmap_set_pattern(bits,numbytes,0,test_vector);
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
if(USE_TEST_VECTOR) { /* Test vector to check that decoding works. */
bitmap_set_pattern(bits, numbytes, 0, test_vector);
numbits = strlen(test_vector);
}
if (numbits < 64) return false; /* Preamble + data. */
if(numbits < 64) return false; /* Preamble + data. */
const char *sync_pattern = "1111010101" "01011010";
uint64_t off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_pattern);
if (off == BITMAP_SEEK_NOT_FOUND) return false;
const char* sync_pattern = "1111010101"
"01011010";
uint64_t off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_pattern);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
FURI_LOG_E(TAG, "Schrader TPMS gap+preamble found");
info->start_off = off;
@@ -34,38 +35,33 @@ static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoView
uint8_t raw[8];
uint8_t id[4];
uint32_t decoded =
convert_from_line_code(raw,sizeof(raw),bits,numbytes,off,
"01","10"); /* Manchester code. */
uint32_t decoded = convert_from_line_code(
raw, sizeof(raw), bits, numbytes, off, "01", "10"); /* Manchester code. */
FURI_LOG_E(TAG, "Schrader TPMS decoded bits: %lu", decoded);
if (decoded < 64) return false; /* Require the full 8 bytes. */
if(decoded < 64) return false; /* Require the full 8 bytes. */
raw[0] |= 0xf0; // Fix the preamble nibble for checksum computation.
uint8_t cksum = crc8(raw,sizeof(raw)-1,0xf0,0x7);
if (cksum != raw[7]) {
uint8_t cksum = crc8(raw, sizeof(raw) - 1, 0xf0, 0x7);
if(cksum != raw[7]) {
FURI_LOG_E(TAG, "Schrader TPMS checksum mismatch");
return false;
}
info->pulses_count = (off+8*8*2) - info->start_off;
info->pulses_count = (off + 8 * 8 * 2) - info->start_off;
float kpa = (float)raw[5]*2.5;
int temp = raw[6]-50;
id[0] = raw[1]&7;
float kpa = (float)raw[5] * 2.5;
int temp = raw[6] - 50;
id[0] = raw[1] & 7;
id[1] = raw[2];
id[2] = raw[3];
id[3] = raw[4];
fieldset_add_bytes(info->fieldset,"Tire ID",id,4*2);
fieldset_add_float(info->fieldset,"Pressure kpa",kpa,2);
fieldset_add_int(info->fieldset,"Temperature C",temp,8);
fieldset_add_bytes(info->fieldset, "Tire ID", id, 4 * 2);
fieldset_add_float(info->fieldset, "Pressure kpa", kpa, 2);
fieldset_add_int(info->fieldset, "Temperature C", temp, 8);
return true;
}
ProtoViewDecoder SchraderTPMSDecoder = {
.name = "Schrader TPMS",
.decode = decode,
.get_fields = NULL,
.build_message = NULL
};
ProtoViewDecoder SchraderTPMSDecoder =
{.name = "Schrader TPMS", .decode = decode, .get_fields = NULL, .build_message = NULL};

47
applications/plugins/protoview/protocols/tpms/schrader_eg53ma4.c
View File

@@ -15,50 +15,45 @@
#include "../../app.h"
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
const char* sync_pattern = "010101010101"
"01100101";
uint8_t sync_len = 12 + 8; /* We just use 12 preamble symbols + sync. */
if(numbits - sync_len + 8 < 8 * 10) return false;
const char *sync_pattern = "010101010101" "01100101";
uint8_t sync_len = 12+8; /* We just use 12 preamble symbols + sync. */
if (numbits-sync_len+8 < 8*10) return false;
uint64_t off = bitmap_seek_bits(bits,numbytes,0,numbits,sync_pattern);
if (off == BITMAP_SEEK_NOT_FOUND) return false;
uint64_t off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync_pattern);
if(off == BITMAP_SEEK_NOT_FOUND) return false;
FURI_LOG_E(TAG, "Schrader EG53MA4 TPMS preamble+sync found");
info->start_off = off;
off += sync_len-8; /* Skip preamble, not sync that is part of the data. */
off += sync_len - 8; /* Skip preamble, not sync that is part of the data. */
uint8_t raw[10];
uint32_t decoded =
convert_from_line_code(raw,sizeof(raw),bits,numbytes,off,
"01","10"); /* Manchester code. */
uint32_t decoded = convert_from_line_code(
raw, sizeof(raw), bits, numbytes, off, "01", "10"); /* Manchester code. */
FURI_LOG_E(TAG, "Schrader EG53MA4 TPMS decoded bits: %lu", decoded);
if (decoded < 10*8) return false; /* Require the full 10 bytes. */
if(decoded < 10 * 8) return false; /* Require the full 10 bytes. */
/* CRC is just all bytes added mod 256. */
uint8_t crc = 0;
for (int j = 0; j < 9; j++) crc += raw[j];
if (crc != raw[9]) return false; /* Require sane CRC. */
for(int j = 0; j < 9; j++) crc += raw[j];
if(crc != raw[9]) return false; /* Require sane CRC. */
info->pulses_count = (off+10*8*2) - info->start_off;
info->pulses_count = (off + 10 * 8 * 2) - info->start_off;
/* To convert the raw pressure to kPa, RTL433 uses 2.5, but is likely
* wrong. Searching on Google for users experimenting with the value
* reported, the value appears to be 2.75. */
float kpa = (float)raw[7]*2.75;
float kpa = (float)raw[7] * 2.75;
int temp_f = raw[8];
int temp_c = (temp_f-32)*5/9; /* Convert Fahrenheit to Celsius. */
int temp_c = (temp_f - 32) * 5 / 9; /* Convert Fahrenheit to Celsius. */
fieldset_add_bytes(info->fieldset,"Tire ID",raw+4,3*2);
fieldset_add_float(info->fieldset,"Pressure kpa",kpa,2);
fieldset_add_int(info->fieldset,"Temperature C",temp_c,8);
fieldset_add_bytes(info->fieldset, "Tire ID", raw + 4, 3 * 2);
fieldset_add_float(info->fieldset, "Pressure kpa", kpa, 2);
fieldset_add_int(info->fieldset, "Temperature C", temp_c, 8);
return true;
}
ProtoViewDecoder SchraderEG53MA4TPMSDecoder = {
.name = "Schrader EG53MA4 TPMS",
.decode = decode,
.get_fields = NULL,
.build_message = NULL
};
ProtoViewDecoder SchraderEG53MA4TPMSDecoder =
{.name = "Schrader EG53MA4 TPMS", .decode = decode, .get_fields = NULL, .build_message = NULL};

57
applications/plugins/protoview/protocols/tpms/toyota.c
View File

@@ -24,40 +24,33 @@
#include "../../app.h"
static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo *info) {
if (numbits-6 < 64*2) return false; /* Ask for 64 bit of data (each bit
static bool decode(uint8_t* bits, uint32_t numbytes, uint32_t numbits, ProtoViewMsgInfo* info) {
if(numbits - 6 < 64 * 2)
return false; /* Ask for 64 bit of data (each bit
is two symbols in the bitmap). */
char *sync[] = {
"00111100",
"001111100",
"00111101",
"001111101",
NULL
};
char* sync[] = {"00111100", "001111100", "00111101", "001111101", NULL};
int j;
uint32_t off = 0;
for (j = 0; sync[j]; j++) {
off = bitmap_seek_bits(bits,numbytes,0,numbits,sync[j]);
if (off != BITMAP_SEEK_NOT_FOUND) {
for(j = 0; sync[j]; j++) {
off = bitmap_seek_bits(bits, numbytes, 0, numbits, sync[j]);
if(off != BITMAP_SEEK_NOT_FOUND) {
info->start_off = off;
off += strlen(sync[j])-2;
off += strlen(sync[j]) - 2;
break;
}
}
}
if (off == BITMAP_SEEK_NOT_FOUND) return false;
if(off == BITMAP_SEEK_NOT_FOUND) return false;
FURI_LOG_E(TAG, "Toyota TPMS sync[%s] found", sync[j]);
uint8_t raw[9];
uint32_t decoded =
convert_from_diff_manchester(raw,sizeof(raw),bits,numbytes,off,true);
uint32_t decoded = convert_from_diff_manchester(raw, sizeof(raw), bits, numbytes, off, true);
FURI_LOG_E(TAG, "Toyota TPMS decoded bits: %lu", decoded);
if (decoded < 8*9) return false; /* Require the full 8 bytes. */
if (crc8(raw,8,0x80,7) != raw[8]) return false; /* Require sane CRC. */
if(decoded < 8 * 9) return false; /* Require the full 8 bytes. */
if(crc8(raw, 8, 0x80, 7) != raw[8]) return false; /* Require sane CRC. */
/* We detected a valid signal. However now info->start_off is actually
* pointing to the sync part, not the preamble of alternating 0 and 1.
@@ -65,25 +58,21 @@ static bool decode(uint8_t *bits, uint32_t numbytes, uint32_t numbits, ProtoView
* for the decoder itself to fix the signal if neeeded, so that its
* logical representation will be more accurate and better to save
* and retransmit. */
if (info->start_off >= 12) {
if(info->start_off >= 12) {
info->start_off -= 12;
bitmap_set_pattern(bits,numbytes,info->start_off,"010101010101");
bitmap_set_pattern(bits, numbytes, info->start_off, "010101010101");
}
info->pulses_count = (off+8*9*2) - info->start_off;
info->pulses_count = (off + 8 * 9 * 2) - info->start_off;
float psi = (float)((raw[4]&0x7f)<<1 | raw[5]>>7) * 0.25 - 7;
int temp = ((raw[5]&0x7f)<<1 | raw[6]>>7) - 40;
float psi = (float)((raw[4] & 0x7f) << 1 | raw[5] >> 7) * 0.25 - 7;
int temp = ((raw[5] & 0x7f) << 1 | raw[6] >> 7) - 40;
fieldset_add_bytes(info->fieldset,"Tire ID",raw,4*2);
fieldset_add_float(info->fieldset,"Pressure psi",psi,2);
fieldset_add_int(info->fieldset,"Temperature C",temp,8);
fieldset_add_bytes(info->fieldset, "Tire ID", raw, 4 * 2);
fieldset_add_float(info->fieldset, "Pressure psi", psi, 2);
fieldset_add_int(info->fieldset, "Temperature C", temp, 8);
return true;
}
ProtoViewDecoder ToyotaTPMSDecoder = {
.name = "Toyota TPMS",
.decode = decode,
.get_fields = NULL,
.build_message = NULL
};
ProtoViewDecoder ToyotaTPMSDecoder =
{.name = "Toyota TPMS", .decode = decode, .get_fields = NULL, .build_message = NULL};

47
applications/plugins/protoview/raw_samples.c
View File

@@ -8,15 +8,15 @@
#include "raw_samples.h"
/* Allocate and initialize a samples buffer. */
RawSamplesBuffer *raw_samples_alloc(void) {
RawSamplesBuffer *buf = malloc(sizeof(*buf));
RawSamplesBuffer* raw_samples_alloc(void) {
RawSamplesBuffer* buf = malloc(sizeof(*buf));
buf->mutex = furi_mutex_alloc(FuriMutexTypeNormal);
raw_samples_reset(buf);
return buf;
}
/* Free a sample buffer. Should be called when the mutex is released. */
void raw_samples_free(RawSamplesBuffer *s) {
void raw_samples_free(RawSamplesBuffer* s) {
furi_mutex_free(s->mutex);
free(s);
}
@@ -24,27 +24,27 @@ void raw_samples_free(RawSamplesBuffer *s) {
/* This just set all the samples to zero and also resets the internal
* index. There is no need to call it after raw_samples_alloc(), but only
* when one wants to reset the whole buffer of samples. */
void raw_samples_reset(RawSamplesBuffer *s) {
furi_mutex_acquire(s->mutex,FuriWaitForever);
void raw_samples_reset(RawSamplesBuffer* s) {
furi_mutex_acquire(s->mutex, FuriWaitForever);
s->total = RAW_SAMPLES_NUM;
s->idx = 0;
s->short_pulse_dur = 0;
memset(s->samples,0,sizeof(s->samples));
memset(s->samples, 0, sizeof(s->samples));
furi_mutex_release(s->mutex);
}
/* Set the raw sample internal index so that what is currently at
* offset 'offset', will appear to be at 0 index. */
void raw_samples_center(RawSamplesBuffer *s, uint32_t offset) {
s->idx = (s->idx+offset) % RAW_SAMPLES_NUM;
void raw_samples_center(RawSamplesBuffer* s, uint32_t offset) {
s->idx = (s->idx + offset) % RAW_SAMPLES_NUM;
}
/* Add the specified sample in the circular buffer. */
void raw_samples_add(RawSamplesBuffer *s, bool level, uint32_t dur) {
furi_mutex_acquire(s->mutex,FuriWaitForever);
void raw_samples_add(RawSamplesBuffer* s, bool level, uint32_t dur) {
furi_mutex_acquire(s->mutex, FuriWaitForever);
s->samples[s->idx].level = level;
s->samples[s->idx].dur = dur;
s->idx = (s->idx+1) % RAW_SAMPLES_NUM;
s->idx = (s->idx + 1) % RAW_SAMPLES_NUM;
furi_mutex_release(s->mutex);
}
@@ -56,28 +56,25 @@ void raw_samples_add(RawSamplesBuffer *s, bool level, uint32_t dur) {
*
* This function is a bit slower so the internal data sampling should
* be performed with raw_samples_add(). */
void raw_samples_add_or_update(RawSamplesBuffer *s, bool level, uint32_t dur) {
furi_mutex_acquire(s->mutex,FuriWaitForever);
uint32_t previdx = (s->idx-1) % RAW_SAMPLES_NUM;
if (s->samples[previdx].level == level &&
s->samples[previdx].dur != 0)
{
void raw_samples_add_or_update(RawSamplesBuffer* s, bool level, uint32_t dur) {
furi_mutex_acquire(s->mutex, FuriWaitForever);
uint32_t previdx = (s->idx - 1) % RAW_SAMPLES_NUM;
if(s->samples[previdx].level == level && s->samples[previdx].dur != 0) {
/* Update the last sample: it has the same level. */
s->samples[previdx].dur += dur;
} else {
/* Add a new sample. */
s->samples[s->idx].level = level;
s->samples[s->idx].dur = dur;
s->idx = (s->idx+1) % RAW_SAMPLES_NUM;
s->idx = (s->idx + 1) % RAW_SAMPLES_NUM;
}
furi_mutex_release(s->mutex);
}
/* Get the sample from the buffer. It is possible to use out of range indexes
* as 'idx' because the modulo operation will rewind back from the start. */
void raw_samples_get(RawSamplesBuffer *s, uint32_t idx, bool *level, uint32_t *dur)
{
furi_mutex_acquire(s->mutex,FuriWaitForever);
void raw_samples_get(RawSamplesBuffer* s, uint32_t idx, bool* level, uint32_t* dur) {
furi_mutex_acquire(s->mutex, FuriWaitForever);
idx = (s->idx + idx) % RAW_SAMPLES_NUM;
*level = s->samples[idx].level;
*dur = s->samples[idx].dur;
@@ -85,12 +82,12 @@ void raw_samples_get(RawSamplesBuffer *s, uint32_t idx, bool *level, uint32_t *d
}
/* Copy one buffer to the other, including current index. */
void raw_samples_copy(RawSamplesBuffer *dst, RawSamplesBuffer *src) {
furi_mutex_acquire(src->mutex,FuriWaitForever);
furi_mutex_acquire(dst->mutex,FuriWaitForever);
void raw_samples_copy(RawSamplesBuffer* dst, RawSamplesBuffer* src) {
furi_mutex_acquire(src->mutex, FuriWaitForever);
furi_mutex_acquire(dst->mutex, FuriWaitForever);
dst->idx = src->idx;
dst->short_pulse_dur = src->short_pulse_dur;
memcpy(dst->samples,src->samples,sizeof(dst->samples));
memcpy(dst->samples, src->samples, sizeof(dst->samples));
furi_mutex_release(src->mutex);
furi_mutex_release(dst->mutex);
}

27
applications/plugins/protoview/raw_samples.h
View File

@@ -4,16 +4,17 @@
/* Our circular buffer of raw samples, used in order to display
* the signal. */
#define RAW_SAMPLES_NUM 2048 /* Use a power of two: we take the modulo
#define RAW_SAMPLES_NUM \
2048 /* Use a power of two: we take the modulo
of the index quite often to normalize inside
the range, and division is slow. */
typedef struct RawSamplesBuffer {
FuriMutex *mutex;
FuriMutex* mutex;
struct {
uint16_t level:1;
uint16_t dur:15;
uint16_t level : 1;
uint16_t dur : 15;
} samples[RAW_SAMPLES_NUM];
uint32_t idx; /* Current idx (next to write). */
uint32_t idx; /* Current idx (next to write). */
uint32_t total; /* Total samples: same as RAW_SAMPLES_NUM, we provide
this field for a cleaner interface with the user, but
we always use RAW_SAMPLES_NUM when taking the modulo so
@@ -22,11 +23,11 @@ typedef struct RawSamplesBuffer {
uint32_t short_pulse_dur; /* Duration of the shortest pulse. */
} RawSamplesBuffer;
RawSamplesBuffer *raw_samples_alloc(void);
void raw_samples_reset(RawSamplesBuffer *s);
void raw_samples_center(RawSamplesBuffer *s, uint32_t offset);
void raw_samples_add(RawSamplesBuffer *s, bool level, uint32_t dur);
void raw_samples_add_or_update(RawSamplesBuffer *s, bool level, uint32_t dur);
void raw_samples_get(RawSamplesBuffer *s, uint32_t idx, bool *level, uint32_t *dur);
void raw_samples_copy(RawSamplesBuffer *dst, RawSamplesBuffer *src);
void raw_samples_free(RawSamplesBuffer *s);
RawSamplesBuffer* raw_samples_alloc(void);
void raw_samples_reset(RawSamplesBuffer* s);
void raw_samples_center(RawSamplesBuffer* s, uint32_t offset);
void raw_samples_add(RawSamplesBuffer* s, bool level, uint32_t dur);
void raw_samples_add_or_update(RawSamplesBuffer* s, bool level, uint32_t dur);
void raw_samples_get(RawSamplesBuffer* s, uint32_t idx, bool* level, uint32_t* dur);
void raw_samples_copy(RawSamplesBuffer* dst, RawSamplesBuffer* src);
void raw_samples_free(RawSamplesBuffer* s);

348
applications/plugins/protoview/signal.c
View File

@@ -3,7 +3,7 @@
#include "app.h"
bool decode_signal(RawSamplesBuffer *s, uint64_t len, ProtoViewMsgInfo *info);
bool decode_signal(RawSamplesBuffer* s, uint64_t len, ProtoViewMsgInfo* info);
/* =============================================================================
* Raw signal detection
@@ -16,7 +16,7 @@ uint32_t duration_delta(uint32_t a, uint32_t b) {
}
/* Reset the current signal, so that a new one can be detected. */
void reset_current_signal(ProtoViewApp *app) {
void reset_current_signal(ProtoViewApp* app) {
app->signal_bestlen = 0;
app->signal_offset = 0;
app->signal_decoded = false;
@@ -39,47 +39,47 @@ void reset_current_signal(ProtoViewApp *app) {
* For instance Oregon2 sensors, in the case of protocol 2.1 will send
* pulses of ~400us (RF on) VS ~580us (RF off). */
#define SEARCH_CLASSES 3
uint32_t search_coherent_signal(RawSamplesBuffer *s, uint32_t idx) {
uint32_t search_coherent_signal(RawSamplesBuffer* s, uint32_t idx) {
struct {
uint32_t dur[2]; /* dur[0] = low, dur[1] = high */
uint32_t count[2]; /* Associated observed frequency. */
uint32_t dur[2]; /* dur[0] = low, dur[1] = high */
uint32_t count[2]; /* Associated observed frequency. */
} classes[SEARCH_CLASSES];
memset(classes,0,sizeof(classes));
memset(classes, 0, sizeof(classes));
uint32_t minlen = 30, maxlen = 4000; /* Depends on data rate, here we
allow for high and low. */
uint32_t len = 0; /* Observed len of coherent samples. */
s->short_pulse_dur = 0;
for (uint32_t j = idx; j < idx+500; j++) {
for(uint32_t j = idx; j < idx + 500; j++) {
bool level;
uint32_t dur;
raw_samples_get(s, j, &level, &dur);
if (dur < minlen || dur > maxlen) break; /* return. */
if(dur < minlen || dur > maxlen) break; /* return. */
/* Let's see if it matches a class we already have or if we
* can populate a new (yet empty) class. */
uint32_t k;
for (k = 0; k < SEARCH_CLASSES; k++) {
if (classes[k].count[level] == 0) {
for(k = 0; k < SEARCH_CLASSES; k++) {
if(classes[k].count[level] == 0) {
classes[k].dur[level] = dur;
classes[k].count[level] = 1;
break; /* Sample accepted. */
} else {
uint32_t classavg = classes[k].dur[level];
uint32_t count = classes[k].count[level];
uint32_t delta = duration_delta(dur,classavg);
uint32_t delta = duration_delta(dur, classavg);
/* Is the difference in duration between this signal and
* the class we are inspecting less than a given percentage?
* If so, accept this signal. */
if (delta < classavg/5) { /* 100%/5 = 20%. */
if(delta < classavg / 5) { /* 100%/5 = 20%. */
/* It is useful to compute the average of the class
* we are observing. We know how many samples we got so
* far, so we can recompute the average easily.
* By always having a better estimate of the pulse len
* we can avoid missing next samples in case the first
* observed samples are too off. */
classavg = ((classavg * count) + dur) / (count+1);
classavg = ((classavg * count) + dur) / (count + 1);
classes[k].dur[level] = classavg;
classes[k].count[level]++;
break; /* Sample accepted. */
@@ -87,7 +87,7 @@ uint32_t search_coherent_signal(RawSamplesBuffer *s, uint32_t idx) {
}
}
if (k == SEARCH_CLASSES) break; /* No match, return. */
if(k == SEARCH_CLASSES) break; /* No match, return. */
/* If we are here, we accepted this sample. Try with the next
* one. */
@@ -97,14 +97,12 @@ uint32_t search_coherent_signal(RawSamplesBuffer *s, uint32_t idx) {
/* Update the buffer setting the shortest pulse we found
* among the three classes. This will be used when scaling
* for visualization. */
uint32_t short_dur[2] = {0,0};
for (int j = 0; j < SEARCH_CLASSES; j++) {
for (int level = 0; level < 2; level++) {
if (classes[j].dur[level] == 0) continue;
if (classes[j].count[level] < 3) continue;
if (short_dur[level] == 0 ||
short_dur[level] > classes[j].dur[level])
{
uint32_t short_dur[2] = {0, 0};
for(int j = 0; j < SEARCH_CLASSES; j++) {
for(int level = 0; level < 2; level++) {
if(classes[j].dur[level] == 0) continue;
if(classes[j].count[level] < 3) continue;
if(short_dur[level] == 0 || short_dur[level] > classes[j].dur[level]) {
short_dur[level] = classes[j].dur[level];
}
}
@@ -113,33 +111,28 @@ uint32_t search_coherent_signal(RawSamplesBuffer *s, uint32_t idx) {
/* Use the average between high and low short pulses duration.
* Often they are a bit different, and using the average is more robust
* when we do decoding sampling at short_pulse_dur intervals. */
if (short_dur[0] == 0) short_dur[0] = short_dur[1];
if (short_dur[1] == 0) short_dur[1] = short_dur[0];
s->short_pulse_dur = (short_dur[0]+short_dur[1])/2;
if(short_dur[0] == 0) short_dur[0] = short_dur[1];
if(short_dur[1] == 0) short_dur[1] = short_dur[0];
s->short_pulse_dur = (short_dur[0] + short_dur[1]) / 2;
return len;
}
/* Called when we detect a message. Just blinks when the message was
* not decoded. Vibrates, too, when the message was correctly decoded. */
void notify_signal_detected(ProtoViewApp *app, bool decoded) {
void notify_signal_detected(ProtoViewApp* app, bool decoded) {
static const NotificationSequence decoded_seq = {
&message_vibro_on,
&message_green_255,
&message_delay_50,
&message_green_0,
&message_vibro_off,
NULL
};
NULL};
static const NotificationSequence unknown_seq = {
&message_red_255,
&message_delay_50,
&message_red_0,
NULL
};
&message_red_255, &message_delay_50, &message_red_0, NULL};
if (decoded)
if(decoded)
notification_message(app->notification, &decoded_seq);
else
notification_message(app->notification, &unknown_seq);
@@ -149,57 +142,59 @@ void notify_signal_detected(ProtoViewApp *app, bool decoded) {
* in order to find a coherent signal. If a signal that does not appear to
* be just noise is found, it is set in DetectedSamples global signal
* buffer, that is what is rendered on the screen. */
void scan_for_signal(ProtoViewApp *app, RawSamplesBuffer *source) {
void scan_for_signal(ProtoViewApp* app, RawSamplesBuffer* source) {
/* We need to work on a copy: the source buffer may be populated
* by the background thread receiving data. */
RawSamplesBuffer *copy = raw_samples_alloc();
raw_samples_copy(copy,source);
RawSamplesBuffer* copy = raw_samples_alloc();
raw_samples_copy(copy, source);
/* Try to seek on data that looks to have a regular high low high low
* pattern. */
uint32_t minlen = 18; /* Min run of coherent samples. With less
uint32_t minlen = 18; /* Min run of coherent samples. With less
than a few samples it's very easy to
mistake noise for signal. */
uint32_t i = 0;
while (i < copy->total-1) {
uint32_t thislen = search_coherent_signal(copy,i);
while(i < copy->total - 1) {
uint32_t thislen = search_coherent_signal(copy, i);
/* For messages that are long enough, attempt decoding. */
if (thislen > minlen) {
if(thislen > minlen) {
/* Allocate the message information that some decoder may
* fill, in case it is able to decode a message. */
ProtoViewMsgInfo *info = malloc(sizeof(ProtoViewMsgInfo));
init_msg_info(info,app);
ProtoViewMsgInfo* info = malloc(sizeof(ProtoViewMsgInfo));
init_msg_info(info, app);
info->short_pulse_dur = copy->short_pulse_dur;
uint32_t saved_idx = copy->idx; /* Save index, see later. */
/* decode_signal() expects the detected signal to start
* from index zero .*/
raw_samples_center(copy,i);
bool decoded = decode_signal(copy,thislen,info);
raw_samples_center(copy, i);
bool decoded = decode_signal(copy, thislen, info);
copy->idx = saved_idx; /* Restore the index as we are scanning
the signal in the loop. */
/* Accept this signal as the new signal if either it's longer
* than the previous undecoded one, or the previous one was
* unknown and this is decoded. */
if ((thislen > app->signal_bestlen && app->signal_decoded == false)
|| (app->signal_decoded == false && decoded))
{
if((thislen > app->signal_bestlen && app->signal_decoded == false) ||
(app->signal_decoded == false && decoded)) {
free_msg_info(app->msg_info);
app->msg_info = info;
app->signal_bestlen = thislen;
app->signal_decoded = decoded;
raw_samples_copy(DetectedSamples,copy);
raw_samples_center(DetectedSamples,i);
FURI_LOG_E(TAG, "===> Displayed sample updated (%d samples %lu us)",
(int)thislen, DetectedSamples->short_pulse_dur);
raw_samples_copy(DetectedSamples, copy);
raw_samples_center(DetectedSamples, i);
FURI_LOG_E(
TAG,
"===> Displayed sample updated (%d samples %lu us)",
(int)thislen,
DetectedSamples->short_pulse_dur);
adjust_raw_view_scale(app,DetectedSamples->short_pulse_dur);
notify_signal_detected(app,decoded);
adjust_raw_view_scale(app, DetectedSamples->short_pulse_dur);
notify_signal_detected(app, decoded);
} else {
/* If the structure was not filled, discard it. Otherwise
* now the owner is app->msg_info. */
@@ -227,38 +222,42 @@ void scan_for_signal(ProtoViewApp *app, RawSamplesBuffer *source) {
/* Set the 'bitpos' bit to value 'val', in the specified bitmap
* 'b' of len 'blen'.
* Out of range bits will silently be discarded. */
void bitmap_set(uint8_t *b, uint32_t blen, uint32_t bitpos, bool val) {
uint32_t byte = bitpos/8;
uint32_t bit = 7-(bitpos&7);
if (byte >= blen) return;
if (val)
b[byte] |= 1<<bit;
void bitmap_set(uint8_t* b, uint32_t blen, uint32_t bitpos, bool val) {
uint32_t byte = bitpos / 8;
uint32_t bit = 7 - (bitpos & 7);
if(byte >= blen) return;
if(val)
b[byte] |= 1 << bit;
else
b[byte] &= ~(1<<bit);
b[byte] &= ~(1 << bit);
}
/* Get the bit 'bitpos' of the bitmap 'b' of 'blen' bytes.
* Out of range bits return false (not bit set). */
bool bitmap_get(uint8_t *b, uint32_t blen, uint32_t bitpos) {
uint32_t byte = bitpos/8;
uint32_t bit = 7-(bitpos&7);
if (byte >= blen) return 0;
return (b[byte] & (1<<bit)) != 0;
bool bitmap_get(uint8_t* b, uint32_t blen, uint32_t bitpos) {
uint32_t byte = bitpos / 8;
uint32_t bit = 7 - (bitpos & 7);
if(byte >= blen) return 0;
return (b[byte] & (1 << bit)) != 0;
}
/* Copy 'count' bits from the bitmap 's' of 'slen' total bytes, to the
* bitmap 'd' of 'dlen' total bytes. The bits are copied starting from
* offset 'soff' of the source bitmap to the offset 'doff' of the
* destination bitmap. */
void bitmap_copy(uint8_t *d, uint32_t dlen, uint32_t doff,
uint8_t *s, uint32_t slen, uint32_t soff,
uint32_t count)
{
void bitmap_copy(
uint8_t* d,
uint32_t dlen,
uint32_t doff,
uint8_t* s,
uint32_t slen,
uint32_t soff,
uint32_t count) {
/* If we are byte-aligned in both source and destination, use a fast
* path for the number of bytes we can consume this way. */
if ((doff & 7) == 0 && (soff & 7) == 0) {
uint32_t didx = doff/8;
uint32_t sidx = soff/8;
if((doff & 7) == 0 && (soff & 7) == 0) {
uint32_t didx = doff / 8;
uint32_t sidx = soff / 8;
while(count > 8 && didx < dlen && sidx < slen) {
d[didx++] = s[sidx++];
count -= 8;
@@ -271,9 +270,9 @@ void bitmap_copy(uint8_t *d, uint32_t dlen, uint32_t doff,
/* Copy the bits needed to reach an offset where we can copy
* two half bytes of src to a full byte of destination. */
while(count > 8 && (doff&7) != 0) {
bool bit = bitmap_get(s,slen,soff++);
bitmap_set(d,dlen,doff++,bit);
while(count > 8 && (doff & 7) != 0) {
bool bit = bitmap_get(s, slen, soff++);
bitmap_set(d, dlen, doff++, bit);
count--;
}
@@ -316,13 +315,12 @@ void bitmap_copy(uint8_t *d, uint32_t dlen, uint32_t doff,
* src[2] << 5, that is "WORLDS!!" >> 5 = ".....WOR"
* That is "HELLOWOR"
*/
if (count > 8) {
if(count > 8) {
uint8_t skew = soff % 8; /* Don't worry, compiler will optimize. */
uint32_t didx = doff/8;
uint32_t sidx = soff/8;
uint32_t didx = doff / 8;
uint32_t sidx = soff / 8;
while(count > 8 && didx < dlen && sidx < slen) {
d[didx] = ((s[sidx] << skew) |
(s[sidx+1] >> (8-skew)));
d[didx] = ((s[sidx] << skew) | (s[sidx + 1] >> (8 - skew)));
sidx++;
didx++;
soff += 8;
@@ -334,8 +332,8 @@ void bitmap_copy(uint8_t *d, uint32_t dlen, uint32_t doff,
/* Here count is guaranteed to be < 8.
* Copy the final bits bit by bit. */
while(count) {
bool bit = bitmap_get(s,slen,soff++);
bitmap_set(d,dlen,doff++,bit);
bool bit = bitmap_get(s, slen, soff++);
bitmap_set(d, dlen, doff++, bit);
count--;
}
}
@@ -343,15 +341,15 @@ void bitmap_copy(uint8_t *d, uint32_t dlen, uint32_t doff,
/* We decode bits assuming the first bit we receive is the MSB
* (see bitmap_set/get functions). Certain devices send data
* encoded in the reverse way. */
void bitmap_reverse_bytes_bits(uint8_t *p, uint32_t len) {
for (uint32_t j = 0; j < len; j++) {
void bitmap_reverse_bytes_bits(uint8_t* p, uint32_t len) {
for(uint32_t j = 0; j < len; j++) {
uint32_t b = p[j];
/* Step 1: swap the two nibbles: 12345678 -> 56781234 */
b = (b&0xf0)>>4 | (b&0x0f)<<4;
b = (b & 0xf0) >> 4 | (b & 0x0f) << 4;
/* Step 2: swap adjacent pairs : 56781234 -> 78563412 */
b = (b&0xcc)>>2 | (b&0x33)<<2;
b = (b & 0xcc) >> 2 | (b & 0x33) << 2;
/* Step 3: swap adjacent bits : 78563412 -> 87654321 */
b = (b&0xaa)>>1 | (b&0x55)<<1;
b = (b & 0xaa) >> 1 | (b & 0x55) << 1;
p[j] = b;
}
}
@@ -359,10 +357,10 @@ void bitmap_reverse_bytes_bits(uint8_t *p, uint32_t len) {
/* Return true if the specified sequence of bits, provided as a string in the
* form "11010110..." is found in the 'b' bitmap of 'blen' bits at 'bitpos'
* position. */
bool bitmap_match_bits(uint8_t *b, uint32_t blen, uint32_t bitpos, const char *bits) {
for (size_t j = 0; bits[j]; j++) {
bool bitmap_match_bits(uint8_t* b, uint32_t blen, uint32_t bitpos, const char* bits) {
for(size_t j = 0; bits[j]; j++) {
bool expected = (bits[j] == '1') ? true : false;
if (bitmap_get(b,blen,bitpos+j) != expected) return false;
if(bitmap_get(b, blen, bitpos + j) != expected) return false;
}
return true;
}
@@ -375,12 +373,17 @@ bool bitmap_match_bits(uint8_t *b, uint32_t blen, uint32_t bitpos, const char *b
* Note: there are better algorithms, such as Boyer-Moore. Here we hope that
* for the kind of patterns we search we'll have a lot of early stops so
* we use a vanilla approach. */
uint32_t bitmap_seek_bits(uint8_t *b, uint32_t blen, uint32_t startpos, uint32_t maxbits, const char *bits) {
uint32_t endpos = startpos+blen*8;
uint32_t end2 = startpos+maxbits;
if (end2 < endpos) endpos = end2;
for (uint32_t j = startpos; j < endpos; j++)
if (bitmap_match_bits(b,blen,j,bits)) return j;
uint32_t bitmap_seek_bits(
uint8_t* b,
uint32_t blen,
uint32_t startpos,
uint32_t maxbits,
const char* bits) {
uint32_t endpos = startpos + blen * 8;
uint32_t end2 = startpos + maxbits;
if(end2 < endpos) endpos = end2;
for(uint32_t j = startpos; j < endpos; j++)
if(bitmap_match_bits(b, blen, j, bits)) return j;
return BITMAP_SEEK_NOT_FOUND;
}
@@ -391,10 +394,10 @@ uint32_t bitmap_seek_bits(uint8_t *b, uint32_t blen, uint32_t startpos, uint32_t
* This function is useful in order to set the test vectors in the protocol
* decoders, to see if the decoding works regardless of the fact we are able
* to actually receive a given signal. */
void bitmap_set_pattern(uint8_t *b, uint32_t blen, uint32_t off, const char *pat) {
void bitmap_set_pattern(uint8_t* b, uint32_t blen, uint32_t off, const char* pat) {
uint32_t i = 0;
while(pat[i]) {
bitmap_set(b,blen,i+off,pat[i] == '1');
bitmap_set(b, blen, i + off, pat[i] == '1');
i++;
}
}
@@ -426,31 +429,36 @@ void bitmap_set_pattern(uint8_t *b, uint32_t blen, uint32_t off, const char *pat
* bits set into the buffer 'b'. The 'rate' argument, in microseconds, is
* the detected short-pulse duration. We expect the line code to be
* meaningful when interpreted at multiples of 'rate'. */
uint32_t convert_signal_to_bits(uint8_t *b, uint32_t blen, RawSamplesBuffer *s, uint32_t idx, uint32_t count, uint32_t rate) {
if (rate == 0) return 0; /* We can't perform the conversion. */
uint32_t convert_signal_to_bits(
uint8_t* b,
uint32_t blen,
RawSamplesBuffer* s,
uint32_t idx,
uint32_t count,
uint32_t rate) {
if(rate == 0) return 0; /* We can't perform the conversion. */
uint32_t bitpos = 0;
for (uint32_t j = 0; j < count; j++) {
for(uint32_t j = 0; j < count; j++) {
uint32_t dur;
bool level;
raw_samples_get(s, j+idx, &level, &dur);
raw_samples_get(s, j + idx, &level, &dur);
uint32_t numbits = dur / rate; /* full bits that surely fit. */
uint32_t rest = dur % rate; /* How much we are left with. */
if (rest > rate/2) numbits++; /* There is another one. */
uint32_t rest = dur % rate; /* How much we are left with. */
if(rest > rate / 2) numbits++; /* There is another one. */
/* Limit how much a single sample can spawn. There are likely no
* protocols doing such long pulses when the rate is low. */
if (numbits > 1024) numbits = 1024;
if(numbits > 1024) numbits = 1024;
if (0) /* Super verbose, so not under the DEBUG_MSG define. */
FURI_LOG_E(TAG, "%lu converted into %lu (%d) bits",
dur,numbits,(int)level);
if(0) /* Super verbose, so not under the DEBUG_MSG define. */
FURI_LOG_E(TAG, "%lu converted into %lu (%d) bits", dur, numbits, (int)level);
/* If the signal is too short, let's claim it an interference
* and ignore it completely. */
if (numbits == 0) continue;
if(numbits == 0) continue;
while(numbits--) bitmap_set(b,blen,bitpos++,level);
while(numbits--) bitmap_set(b, blen, bitpos++, level);
}
return bitpos;
}
@@ -467,23 +475,29 @@ uint32_t convert_signal_to_bits(uint8_t *b, uint32_t blen, RawSamplesBuffer *s,
* specified in bytes by the caller, via the 'len' parameters).
*
* The decoding starts at the specified offset (in bits) 'off'. */
uint32_t convert_from_line_code(uint8_t *buf, uint64_t buflen, uint8_t *bits, uint32_t len, uint32_t off, const char *zero_pattern, const char *one_pattern)
{
uint32_t convert_from_line_code(
uint8_t* buf,
uint64_t buflen,
uint8_t* bits,
uint32_t len,
uint32_t off,
const char* zero_pattern,
const char* one_pattern) {
uint32_t decoded = 0; /* Number of bits extracted. */
len *= 8; /* Convert bytes to bits. */
while(off < len) {
bool bitval;
if (bitmap_match_bits(bits,len,off,zero_pattern)) {
if(bitmap_match_bits(bits, len, off, zero_pattern)) {
bitval = false;
off += strlen(zero_pattern);
} else if (bitmap_match_bits(bits,len,off,one_pattern)) {
} else if(bitmap_match_bits(bits, len, off, one_pattern)) {
bitval = true;
off += strlen(one_pattern);
} else {
break;
}
bitmap_set(buf,buflen,decoded++,bitval);
if (decoded/8 == buflen) break; /* No space left on target buffer. */
bitmap_set(buf, buflen, decoded++, bitval);
if(decoded / 8 == buflen) break; /* No space left on target buffer. */
}
return decoded;
}
@@ -494,17 +508,22 @@ uint32_t convert_from_line_code(uint8_t *buf, uint64_t buflen, uint8_t *bits, ui
* in differential codings the next bits depend on the previous one.
*
* Parameters and return values are like convert_from_line_code(). */
uint32_t convert_from_diff_manchester(uint8_t *buf, uint64_t buflen, uint8_t *bits, uint32_t len, uint32_t off, bool previous)
{
uint32_t convert_from_diff_manchester(
uint8_t* buf,
uint64_t buflen,
uint8_t* bits,
uint32_t len,
uint32_t off,
bool previous) {
uint32_t decoded = 0;
len *= 8; /* Conver to bits. */
for (uint32_t j = off; j < len; j += 2) {
bool b0 = bitmap_get(bits,len,j);
bool b1 = bitmap_get(bits,len,j+1);
if (b0 == previous) break; /* Each new bit must switch value. */
bitmap_set(buf,buflen,decoded++,b0 == b1);
for(uint32_t j = off; j < len; j += 2) {
bool b0 = bitmap_get(bits, len, j);
bool b1 = bitmap_get(bits, len, j + 1);
if(b0 == previous) break; /* Each new bit must switch value. */
bitmap_set(buf, buflen, decoded++, b0 == b1);
previous = b1;
if (decoded/8 == buflen) break; /* No space left on target buffer. */
if(decoded / 8 == buflen) break; /* No space left on target buffer. */
}
return decoded;
}
@@ -522,22 +541,21 @@ extern ProtoViewDecoder CitroenTPMSDecoder;
extern ProtoViewDecoder FordTPMSDecoder;
extern ProtoViewDecoder KeeloqDecoder;
ProtoViewDecoder *Decoders[] = {
&Oregon2Decoder, /* Oregon sensors v2.1 protocol. */
&B4B1Decoder, /* PT, SC, ... 24 bits remotes. */
&RenaultTPMSDecoder, /* Renault TPMS. */
&ToyotaTPMSDecoder, /* Toyota TPMS. */
&SchraderTPMSDecoder, /* Schrader TPMS. */
&SchraderEG53MA4TPMSDecoder, /* Schrader EG53MA4 TPMS. */
&CitroenTPMSDecoder, /* Citroen TPMS. */
&FordTPMSDecoder, /* Ford TPMS. */
&KeeloqDecoder, /* Keeloq remote. */
NULL
};
ProtoViewDecoder* Decoders[] = {
&Oregon2Decoder, /* Oregon sensors v2.1 protocol. */
&B4B1Decoder, /* PT, SC, ... 24 bits remotes. */
&RenaultTPMSDecoder, /* Renault TPMS. */
&ToyotaTPMSDecoder, /* Toyota TPMS. */
&SchraderTPMSDecoder, /* Schrader TPMS. */
&SchraderEG53MA4TPMSDecoder, /* Schrader EG53MA4 TPMS. */
&CitroenTPMSDecoder, /* Citroen TPMS. */
&FordTPMSDecoder, /* Ford TPMS. */
&KeeloqDecoder, /* Keeloq remote. */
NULL};
/* Free the message info and allocated data. */
void free_msg_info(ProtoViewMsgInfo *i) {
if (i == NULL) return;
void free_msg_info(ProtoViewMsgInfo* i) {
if(i == NULL) return;
fieldset_free(i->fieldset);
free(i->bits);
free(i);
@@ -545,9 +563,9 @@ void free_msg_info(ProtoViewMsgInfo *i) {
/* Reset the message info structure before passing it to the decoding
* functions. */
void init_msg_info(ProtoViewMsgInfo *i, ProtoViewApp *app) {
void init_msg_info(ProtoViewMsgInfo* i, ProtoViewApp* app) {
UNUSED(app);
memset(i,0,sizeof(ProtoViewMsgInfo));
memset(i, 0, sizeof(ProtoViewMsgInfo));
i->bits = NULL;
i->fieldset = fieldset_new();
}
@@ -556,23 +574,29 @@ void init_msg_info(ProtoViewMsgInfo *i, ProtoViewApp *app) {
* to a bitstream, and the calls the protocol specific functions for
* decoding. If the signal was decoded correctly by some protocol, true
* is returned. Otherwise false is returned. */
bool decode_signal(RawSamplesBuffer *s, uint64_t len, ProtoViewMsgInfo *info) {
uint32_t bitmap_bits_size = 4096*8;
uint32_t bitmap_size = bitmap_bits_size/8;
bool decode_signal(RawSamplesBuffer* s, uint64_t len, ProtoViewMsgInfo* info) {
uint32_t bitmap_bits_size = 4096 * 8;
uint32_t bitmap_size = bitmap_bits_size / 8;
/* We call the decoders with an offset a few samples before the actual
* signal detected and for a len of a few bits after its end. */
uint32_t before_samples = 32;
uint32_t after_samples = 100;
uint8_t *bitmap = malloc(bitmap_size);
uint32_t bits = convert_signal_to_bits(bitmap,bitmap_size,s,-before_samples,len+before_samples+after_samples,s->short_pulse_dur);
uint8_t* bitmap = malloc(bitmap_size);
uint32_t bits = convert_signal_to_bits(
bitmap,
bitmap_size,
s,
-before_samples,
len + before_samples + after_samples,
s->short_pulse_dur);
if (DEBUG_MSG) { /* Useful for debugging purposes. Don't remove. */
char *str = malloc(1024);
if(DEBUG_MSG) { /* Useful for debugging purposes. Don't remove. */
char* str = malloc(1024);
uint32_t j;
for (j = 0; j < bits && j < 1023; j++) {
str[j] = bitmap_get(bitmap,bitmap_size,j) ? '1' : '0';
for(j = 0; j < bits && j < 1023; j++) {
str[j] = bitmap_get(bitmap, bitmap_size, j) ? '1' : '0';
}
str[j] = 0;
FURI_LOG_E(TAG, "%lu bits sampled: %s", bits, str);
@@ -585,18 +609,17 @@ bool decode_signal(RawSamplesBuffer *s, uint64_t len, ProtoViewMsgInfo *info) {
bool decoded = false;
while(Decoders[j]) {
uint32_t start_time = furi_get_tick();
decoded = Decoders[j]->decode(bitmap,bitmap_size,bits,info);
decoded = Decoders[j]->decode(bitmap, bitmap_size, bits, info);
uint32_t delta = furi_get_tick() - start_time;
FURI_LOG_E(TAG, "Decoder %s took %lu ms",
Decoders[j]->name, (unsigned long)delta);
if (decoded) {
FURI_LOG_E(TAG, "Decoder %s took %lu ms", Decoders[j]->name, (unsigned long)delta);
if(decoded) {
info->decoder = Decoders[j];
break;
}
j++;
}
if (!decoded) {
if(!decoded) {
FURI_LOG_E(TAG, "No decoding possible");
} else {
FURI_LOG_E(TAG, "+++ Decoded %s", info->decoder->name);
@@ -604,12 +627,17 @@ bool decode_signal(RawSamplesBuffer *s, uint64_t len, ProtoViewMsgInfo *info) {
* with the decoded signal. The decoder may not implement offset/len
* filling of the structure. In such case we have no info and
* pulses_count will be set to zero. */
if (info->pulses_count) {
info->bits_bytes = (info->pulses_count+7)/8; // Round to full byte.
if(info->pulses_count) {
info->bits_bytes = (info->pulses_count + 7) / 8; // Round to full byte.
info->bits = malloc(info->bits_bytes);
bitmap_copy(info->bits,info->bits_bytes,0,
bitmap,bitmap_size,info->start_off,
info->pulses_count);
bitmap_copy(
info->bits,
info->bits_bytes,
0,
bitmap,
bitmap_size,
info->start_off,
info->pulses_count);
}
}
free(bitmap);

96
applications/plugins/protoview/signal_file.c
View File

@@ -13,57 +13,56 @@
* but it's logical representation stored in the app->msg_info bitmap, where
* each 1 or 0 means a puls or gap for the specified short pulse duration time
* (te). */
bool save_signal(ProtoViewApp *app, const char *filename) {
bool save_signal(ProtoViewApp* app, const char* filename) {
/* We have a message at all? */
if (app->msg_info == NULL || app->msg_info->pulses_count == 0) return false;
Storage *storage = furi_record_open(RECORD_STORAGE);
FlipperFormat *file = flipper_format_file_alloc(storage);
Stream *stream = flipper_format_get_raw_stream(file);
FuriString *file_content = NULL;
if(app->msg_info == NULL || app->msg_info->pulses_count == 0) return false;
Storage* storage = furi_record_open(RECORD_STORAGE);
FlipperFormat* file = flipper_format_file_alloc(storage);
Stream* stream = flipper_format_get_raw_stream(file);
FuriString* file_content = NULL;
bool success = true;
if (flipper_format_file_open_always(file, filename)) {
if(flipper_format_file_open_always(file, filename)) {
/* Write the file header. */
FuriString *file_content = furi_string_alloc();
const char *preset_id = ProtoViewModulations[app->modulation].id;
FuriString* file_content = furi_string_alloc();
const char* preset_id = ProtoViewModulations[app->modulation].id;
furi_string_printf(file_content,
"Filetype: Flipper SubGhz RAW File\n"
"Version: 1\n"
"Frequency: %ld\n"
"Preset: %s\n",
app->frequency,
preset_id ? preset_id : "FuriHalSubGhzPresetCustom");
furi_string_printf(
file_content,
"Filetype: Flipper SubGhz RAW File\n"
"Version: 1\n"
"Frequency: %ld\n"
"Preset: %s\n",
app->frequency,
preset_id ? preset_id : "FuriHalSubGhzPresetCustom");
/* For custom modulations, we need to emit a set of registers. */
if (preset_id == NULL) {
FuriString *custom = furi_string_alloc();
uint8_t *regs = ProtoViewModulations[app->modulation].custom;
furi_string_printf(custom,
if(preset_id == NULL) {
FuriString* custom = furi_string_alloc();
uint8_t* regs = ProtoViewModulations[app->modulation].custom;
furi_string_printf(
custom,
"Custom_preset_module: CC1101\n"
"Custom_preset_data: ");
for (int j = 0; regs[j]; j += 2) {
furi_string_cat_printf(custom, "%02X %02X ",
(int)regs[j], (int)regs[j+1]);
"Custom_preset_data: ");
for(int j = 0; regs[j]; j += 2) {
furi_string_cat_printf(custom, "%02X %02X ", (int)regs[j], (int)regs[j + 1]);
}
size_t len = furi_string_size(file_content);
furi_string_set_char(custom,len-1,'\n');
furi_string_cat(file_content,custom);
furi_string_set_char(custom, len - 1, '\n');
furi_string_cat(file_content, custom);
furi_string_free(custom);
}
/* We always save raw files. */
furi_string_cat_printf(file_content,
"Protocol: RAW\n"
"RAW_Data: -10000\n"); // Start with 10 ms of gap
furi_string_cat_printf(
file_content,
"Protocol: RAW\n"
"RAW_Data: -10000\n"); // Start with 10 ms of gap
/* Write header. */
size_t len = furi_string_size(file_content);
if (stream_write(stream,
(uint8_t*) furi_string_get_cstr(file_content), len)
!= len)
{
if(stream_write(stream, (uint8_t*)furi_string_get_cstr(file_content), len) != len) {
FURI_LOG_W(TAG, "Short write to file");
success = false;
goto write_err;
@@ -76,15 +75,13 @@ bool save_signal(ProtoViewApp *app, const char *filename) {
uint32_t this_line_samples = 0;
uint32_t max_line_samples = 100;
uint32_t idx = 0; // Iindex in the signal bitmap.
ProtoViewMsgInfo *i = app->msg_info;
ProtoViewMsgInfo* i = app->msg_info;
while(idx < i->pulses_count) {
bool level = bitmap_get(i->bits,i->bits_bytes,idx);
bool level = bitmap_get(i->bits, i->bits_bytes, idx);
uint32_t te_times = 1;
idx++;
/* Count the duration of the current pulse/gap. */
while(idx < i->pulses_count &&
bitmap_get(i->bits,i->bits_bytes,idx) == level)
{
while(idx < i->pulses_count && bitmap_get(i->bits, i->bits_bytes, idx) == level) {
te_times++;
idx++;
}
@@ -92,32 +89,29 @@ bool save_signal(ProtoViewApp *app, const char *filename) {
// next gap or pulse.
int32_t dur = (int32_t)i->short_pulse_dur * te_times;
if (level == 0) dur = -dur; /* Negative is gap in raw files. */
if(level == 0) dur = -dur; /* Negative is gap in raw files. */
/* Emit the sample. If this is the first sample of the line,
* also emit the RAW_Data: field. */
if (this_line_samples == 0)
furi_string_cat_printf(file_content,"RAW_Data: ");
furi_string_cat_printf(file_content,"%d ",(int)dur);
if(this_line_samples == 0) furi_string_cat_printf(file_content, "RAW_Data: ");
furi_string_cat_printf(file_content, "%d ", (int)dur);
this_line_samples++;
/* Store the current set of samples on disk, when we reach a
* given number or the end of the signal. */
bool end_reached = (idx == i->pulses_count);
if (this_line_samples == max_line_samples || end_reached) {
if(this_line_samples == max_line_samples || end_reached) {
/* If that's the end, terminate the signal with a long
* gap. */
if (end_reached) furi_string_cat_printf(file_content,"-10000 ");
if(end_reached) furi_string_cat_printf(file_content, "-10000 ");
/* We always have a trailing space in the last sample. Make it
* a newline. */
size_t len = furi_string_size(file_content);
furi_string_set_char(file_content,len-1,'\n');
furi_string_set_char(file_content, len - 1, '\n');
if (stream_write(stream,
(uint8_t*) furi_string_get_cstr(file_content),
len) != len)
{
if(stream_write(stream, (uint8_t*)furi_string_get_cstr(file_content), len) !=
len) {
FURI_LOG_W(TAG, "Short write to file");
success = false;
goto write_err;
@@ -136,6 +130,6 @@ bool save_signal(ProtoViewApp *app, const char *filename) {
write_err:
furi_record_close(RECORD_STORAGE);
flipper_format_free(file);
if (file_content != NULL) furi_string_free(file_content);
if(file_content != NULL) furi_string_free(file_content);
return success;
}

99
applications/plugins/protoview/ui.c
View File

@@ -10,36 +10,31 @@
/* Return the ID of the currently selected subview, of the current
* view. */
int ui_get_current_subview(ProtoViewApp *app) {
int ui_get_current_subview(ProtoViewApp* app) {
return app->current_subview[app->current_view];
}
/* Called by view rendering callback that has subviews, to show small triangles
* facing down/up if there are other subviews the user can access with up
* and down. */
void ui_show_available_subviews(Canvas *canvas, ProtoViewApp *app,
int last_subview)
{
void ui_show_available_subviews(Canvas* canvas, ProtoViewApp* app, int last_subview) {
int subview = ui_get_current_subview(app);
if (subview != 0)
canvas_draw_triangle(canvas,120,5,8,5,CanvasDirectionBottomToTop);
if (subview != last_subview-1)
canvas_draw_triangle(canvas,120,59,8,5,CanvasDirectionTopToBottom);
if(subview != 0) canvas_draw_triangle(canvas, 120, 5, 8, 5, CanvasDirectionBottomToTop);
if(subview != last_subview - 1)
canvas_draw_triangle(canvas, 120, 59, 8, 5, CanvasDirectionTopToBottom);
}
/* Handle up/down keys when we are in a subview. If the function catched
* such keypress, it returns true, so that the actual view input callback
* knows it can just return ASAP without doing anything. */
bool ui_process_subview_updown(ProtoViewApp *app, InputEvent input, int last_subview) {
bool ui_process_subview_updown(ProtoViewApp* app, InputEvent input, int last_subview) {
int subview = ui_get_current_subview(app);
if (input.type == InputTypePress) {
if (input.key == InputKeyUp) {
if (subview != 0)
app->current_subview[app->current_view]--;
if(input.type == InputTypePress) {
if(input.key == InputKeyUp) {
if(subview != 0) app->current_subview[app->current_view]--;
return true;
} else if (input.key == InputKeyDown) {
if (subview != last_subview-1)
app->current_subview[app->current_view]++;
} else if(input.key == InputKeyDown) {
if(subview != last_subview - 1) app->current_subview[app->current_view]++;
return true;
}
}
@@ -62,16 +57,18 @@ bool ui_process_subview_updown(ProtoViewApp *app, InputEvent input, int last_sub
*
* Note: if the buffer is not a null-termined zero string, what it contains will
* be used as initial input for the user. */
void ui_show_keyboard(ProtoViewApp *app, char *buffer, uint32_t buflen,
void (*done_callback)(void*))
{
void ui_show_keyboard(
ProtoViewApp* app,
char* buffer,
uint32_t buflen,
void (*done_callback)(void*)) {
app->show_text_input = true;
app->text_input_buffer = buffer;
app->text_input_buffer_len = buflen;
app->text_input_done_callback = done_callback;
}
void ui_dismiss_keyboard(ProtoViewApp *app) {
void ui_dismiss_keyboard(ProtoViewApp* app) {
view_dispatcher_stop(app->view_dispatcher);
}
@@ -79,24 +76,24 @@ void ui_dismiss_keyboard(ProtoViewApp *app) {
/* Set an alert message to be shown over any currently active view, for
* the specified amount of time of 'ttl' milliseconds. */
void ui_show_alert(ProtoViewApp *app, const char *text, uint32_t ttl) {
void ui_show_alert(ProtoViewApp* app, const char* text, uint32_t ttl) {
app->alert_dismiss_time = furi_get_tick() + furi_ms_to_ticks(ttl);
snprintf(app->alert_text,ALERT_MAX_LEN,"%s",text);
snprintf(app->alert_text, ALERT_MAX_LEN, "%s", text);
}
/* Cancel the alert before its time has elapsed. */
void ui_dismiss_alert(ProtoViewApp *app) {
void ui_dismiss_alert(ProtoViewApp* app) {
app->alert_dismiss_time = 0;
}
/* Show the alert if an alert is set. This is called after the currently
* active view displayed its stuff, so we overwrite the screen with the
* alert message. */
void ui_draw_alert_if_needed(Canvas *canvas, ProtoViewApp *app) {
if (app->alert_dismiss_time == 0) {
void ui_draw_alert_if_needed(Canvas* canvas, ProtoViewApp* app) {
if(app->alert_dismiss_time == 0) {
/* No active alert. */
return;
} else if (app->alert_dismiss_time < furi_get_tick()) {
} else if(app->alert_dismiss_time < furi_get_tick()) {
/* Alert just expired. */
ui_dismiss_alert(app);
return;
@@ -106,41 +103,43 @@ void ui_draw_alert_if_needed(Canvas *canvas, ProtoViewApp *app) {
canvas_set_font(canvas, FontPrimary);
uint8_t w = canvas_string_width(canvas, app->alert_text);
uint8_t h = 8; // Font height.
uint8_t text_x = 64-(w/2);
uint8_t text_y = 32+4;
uint8_t text_x = 64 - (w / 2);
uint8_t text_y = 32 + 4;
uint8_t padding = 3;
canvas_set_color(canvas,ColorBlack);
canvas_draw_box(canvas,text_x-padding,text_y-padding-h,w+padding*2,h+padding*2);
canvas_set_color(canvas,ColorWhite);
canvas_draw_box(canvas,text_x-padding+1,text_y-padding-h+1,w+padding*2-2,h+padding*2-2);
canvas_set_color(canvas,ColorBlack);
canvas_draw_str(canvas,text_x,text_y,app->alert_text);
canvas_set_color(canvas, ColorBlack);
canvas_draw_box(
canvas, text_x - padding, text_y - padding - h, w + padding * 2, h + padding * 2);
canvas_set_color(canvas, ColorWhite);
canvas_draw_box(
canvas,
text_x - padding + 1,
text_y - padding - h + 1,
w + padding * 2 - 2,
h + padding * 2 - 2);
canvas_set_color(canvas, ColorBlack);
canvas_draw_str(canvas, text_x, text_y, app->alert_text);
}
/* =========================== Canvas extensions ============================ */
void canvas_draw_str_with_border(Canvas* canvas, uint8_t x, uint8_t y, const char* str, Color text_color, Color border_color)
{
void canvas_draw_str_with_border(
Canvas* canvas,
uint8_t x,
uint8_t y,
const char* str,
Color text_color,
Color border_color) {
struct {
uint8_t x; uint8_t y;
} dir[8] = {
{-1,-1},
{0,-1},
{1,-1},
{1,0},
{1,1},
{0,1},
{-1,1},
{-1,0}
};
uint8_t x;
uint8_t y;
} dir[8] = {{-1, -1}, {0, -1}, {1, -1}, {1, 0}, {1, 1}, {0, 1}, {-1, 1}, {-1, 0}};
/* Rotate in all the directions writing the same string to create a
* border, then write the actual string in the other color in the
* middle. */
canvas_set_color(canvas, border_color);
for (int j = 0; j < 8; j++)
canvas_draw_str(canvas,x+dir[j].x,y+dir[j].y,str);
for(int j = 0; j < 8; j++) canvas_draw_str(canvas, x + dir[j].x, y + dir[j].y, str);
canvas_set_color(canvas, text_color);
canvas_draw_str(canvas,x,y,str);
canvas_draw_str(canvas, x, y, str);
canvas_set_color(canvas, ColorBlack);
}

211
applications/plugins/protoview/view_build.c
View File

@@ -3,39 +3,38 @@
#include "app.h"
extern ProtoViewDecoder *Decoders[]; // Defined in signal.c.
extern ProtoViewDecoder* Decoders[]; // Defined in signal.c.
/* Our view private data. */
#define USER_VALUE_LEN 64
typedef struct {
ProtoViewDecoder *decoder; /* Decoder we are using to create a
ProtoViewDecoder* decoder; /* Decoder we are using to create a
message. */
uint32_t cur_decoder; /* Decoder index when we are yet selecting
uint32_t cur_decoder; /* Decoder index when we are yet selecting
a decoder. Used when decoder is NULL. */
ProtoViewFieldSet *fieldset; /* The fields to populate. */
uint32_t cur_field; /* Field we are editing right now. This
ProtoViewFieldSet* fieldset; /* The fields to populate. */
uint32_t cur_field; /* Field we are editing right now. This
is the index inside the 'fieldset'
fields. */
char *user_value; /* Keyboard input to replace the current
char* user_value; /* Keyboard input to replace the current
field value goes here. */
} BuildViewPrivData;
/* Not all the decoders support message bulding, so we can't just
* increment / decrement the cur_decoder index here. */
static void select_next_decoder(ProtoViewApp *app) {
BuildViewPrivData *privdata = app->view_privdata;
do {
static void select_next_decoder(ProtoViewApp* app) {
BuildViewPrivData* privdata = app->view_privdata;
do {
privdata->cur_decoder++;
if (Decoders[privdata->cur_decoder] == NULL)
privdata->cur_decoder = 0;
if(Decoders[privdata->cur_decoder] == NULL) privdata->cur_decoder = 0;
} while(Decoders[privdata->cur_decoder]->get_fields == NULL);
}
/* Like select_next_decoder() but goes backward. */
static void select_prev_decoder(ProtoViewApp *app) {
BuildViewPrivData *privdata = app->view_privdata;
static void select_prev_decoder(ProtoViewApp* app) {
BuildViewPrivData* privdata = app->view_privdata;
do {
if (privdata->cur_decoder == 0) {
if(privdata->cur_decoder == 0) {
/* Go one after the last one to wrap around. */
while(Decoders[privdata->cur_decoder]) privdata->cur_decoder++;
}
@@ -45,69 +44,73 @@ static void select_prev_decoder(ProtoViewApp *app) {
/* Render the view to select the decoder, among the ones that
* support message building. */
static void render_view_select_decoder(Canvas *const canvas, ProtoViewApp *app) {
BuildViewPrivData *privdata = app->view_privdata;
static void render_view_select_decoder(Canvas* const canvas, ProtoViewApp* app) {
BuildViewPrivData* privdata = app->view_privdata;
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas, 0, 9, "Signal creator");
canvas_set_font(canvas, FontSecondary);
canvas_draw_str(canvas, 0, 19, "up/down: select, ok: choose");
canvas_set_font(canvas, FontPrimary);
canvas_draw_str_aligned(canvas,64,38,AlignCenter,AlignCenter,
Decoders[privdata->cur_decoder]->name);
canvas_draw_str_aligned(
canvas, 64, 38, AlignCenter, AlignCenter, Decoders[privdata->cur_decoder]->name);
}
/* Render the view that allows the user to populate the fields needed
* for the selected decoder to build a message. */
static void render_view_set_fields(Canvas *const canvas, ProtoViewApp *app) {
BuildViewPrivData *privdata = app->view_privdata;
static void render_view_set_fields(Canvas* const canvas, ProtoViewApp* app) {
BuildViewPrivData* privdata = app->view_privdata;
char buf[32];
snprintf(buf,sizeof(buf), "%s field %d/%d",
privdata->decoder->name, (int)privdata->cur_field+1,
snprintf(
buf,
sizeof(buf),
"%s field %d/%d",
privdata->decoder->name,
(int)privdata->cur_field + 1,
(int)privdata->fieldset->numfields);
canvas_set_color(canvas,ColorBlack);
canvas_draw_box(canvas,0,0,128,21);
canvas_set_color(canvas,ColorWhite);
canvas_set_color(canvas, ColorBlack);
canvas_draw_box(canvas, 0, 0, 128, 21);
canvas_set_color(canvas, ColorWhite);
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas, 1, 9, buf);
canvas_set_font(canvas, FontSecondary);
canvas_draw_str(canvas, 1, 19, "up/down: next field, ok: edit");
/* Write the field name, type, current content. */
canvas_set_color(canvas,ColorBlack);
ProtoViewField *field = privdata->fieldset->fields[privdata->cur_field];
snprintf(buf,sizeof(buf), "%s %s:%d", field->name,
field_get_type_name(field), (int)field->len);
canvas_set_color(canvas, ColorBlack);
ProtoViewField* field = privdata->fieldset->fields[privdata->cur_field];
snprintf(
buf, sizeof(buf), "%s %s:%d", field->name, field_get_type_name(field), (int)field->len);
buf[0] = toupper(buf[0]);
canvas_set_font(canvas, FontPrimary);
canvas_draw_str_aligned(canvas,64,30,AlignCenter,AlignCenter,buf);
canvas_draw_str_aligned(canvas, 64, 30, AlignCenter, AlignCenter, buf);
canvas_set_font(canvas, FontSecondary);
/* Render the current value between "" */
unsigned int written = (unsigned int) field_to_string(buf+1,sizeof(buf)-1,field);
unsigned int written = (unsigned int)field_to_string(buf + 1, sizeof(buf) - 1, field);
buf[0] = '"';
if (written+3 < sizeof(buf)) memcpy(buf+written+1,"\"\x00",2);
canvas_draw_str_aligned(canvas,63,45,AlignCenter,AlignCenter,buf);
if(written + 3 < sizeof(buf)) memcpy(buf + written + 1, "\"\x00", 2);
canvas_draw_str_aligned(canvas, 63, 45, AlignCenter, AlignCenter, buf);
/* Footer instructions. */
canvas_draw_str(canvas, 0, 62, "Long ok: create, < > incr/decr");
}
/* Render the build message view. */
void render_view_build_message(Canvas *const canvas, ProtoViewApp *app) {
BuildViewPrivData *privdata = app->view_privdata;
void render_view_build_message(Canvas* const canvas, ProtoViewApp* app) {
BuildViewPrivData* privdata = app->view_privdata;
if (privdata->decoder)
render_view_set_fields(canvas,app);
if(privdata->decoder)
render_view_set_fields(canvas, app);
else
render_view_select_decoder(canvas,app);
render_view_select_decoder(canvas, app);
}
/* Handle input for the decoder selection. */
static void process_input_select_decoder(ProtoViewApp *app, InputEvent input) {
BuildViewPrivData *privdata = app->view_privdata;
if (input.type == InputTypeShort) {
if (input.key == InputKeyOk) {
static void process_input_select_decoder(ProtoViewApp* app, InputEvent input) {
BuildViewPrivData* privdata = app->view_privdata;
if(input.type == InputTypeShort) {
if(input.key == InputKeyOk) {
privdata->decoder = Decoders[privdata->cur_decoder];
privdata->fieldset = fieldset_new();
privdata->decoder->get_fields(privdata->fieldset);
@@ -116,11 +119,8 @@ static void process_input_select_decoder(ProtoViewApp *app, InputEvent input) {
* same decoder the user selected, let's populate the
* defaults with the current values. So the user will
* actaully edit the current message. */
if (app->signal_decoded &&
app->msg_info->decoder == privdata->decoder)
{
fieldset_copy_matching_fields(privdata->fieldset,
app->msg_info->fieldset);
if(app->signal_decoded && app->msg_info->decoder == privdata->decoder) {
fieldset_copy_matching_fields(privdata->fieldset, app->msg_info->fieldset);
}
/* Now we use the subview system in order to protect the
@@ -128,10 +128,10 @@ static void process_input_select_decoder(ProtoViewApp *app, InputEvent input) {
Since we are technically into a subview now, we'll have
control of < and >. */
InputEvent ii = {.type = InputTypePress, .key = InputKeyDown};
ui_process_subview_updown(app,ii,2);
} else if (input.key == InputKeyDown) {
ui_process_subview_updown(app, ii, 2);
} else if(input.key == InputKeyDown) {
select_next_decoder(app);
} else if (input.key == InputKeyUp) {
} else if(input.key == InputKeyUp) {
select_prev_decoder(app);
}
}
@@ -140,12 +140,13 @@ static void process_input_select_decoder(ProtoViewApp *app, InputEvent input) {
/* Called after the user typed the new field value in the keyboard.
* Let's save it and remove the keyboard view. */
static void text_input_done_callback(void* context) {
ProtoViewApp *app = context;
BuildViewPrivData *privdata = app->view_privdata;
ProtoViewApp* app = context;
BuildViewPrivData* privdata = app->view_privdata;
if (field_set_from_string(privdata->fieldset->fields[privdata->cur_field],
privdata->user_value, strlen(privdata->user_value)) == false)
{
if(field_set_from_string(
privdata->fieldset->fields[privdata->cur_field],
privdata->user_value,
strlen(privdata->user_value)) == false) {
ui_show_alert(app, "Invalid value", 1500);
}
@@ -160,94 +161,88 @@ static void text_input_done_callback(void* context) {
* decrement the current field in a much simpler way.
*
* The current filed is changed by 'incr' amount. */
static bool increment_current_field(ProtoViewApp *app, int incr) {
BuildViewPrivData *privdata = app->view_privdata;
ProtoViewFieldSet *fs = privdata->fieldset;
ProtoViewField *f = fs->fields[privdata->cur_field];
return field_incr_value(f,incr);
static bool increment_current_field(ProtoViewApp* app, int incr) {
BuildViewPrivData* privdata = app->view_privdata;
ProtoViewFieldSet* fs = privdata->fieldset;
ProtoViewField* f = fs->fields[privdata->cur_field];
return field_incr_value(f, incr);
}
/* Handle input for fields editing mode. */
static void process_input_set_fields(ProtoViewApp *app, InputEvent input) {
BuildViewPrivData *privdata = app->view_privdata;
ProtoViewFieldSet *fs = privdata->fieldset;
static void process_input_set_fields(ProtoViewApp* app, InputEvent input) {
BuildViewPrivData* privdata = app->view_privdata;
ProtoViewFieldSet* fs = privdata->fieldset;
if (input.type == InputTypeShort && input.key == InputKeyOk) {
if(input.type == InputTypeShort && input.key == InputKeyOk) {
/* Show the keyboard to let the user type the new
* value. */
if (privdata->user_value == NULL)
privdata->user_value = malloc(USER_VALUE_LEN);
field_to_string(privdata->user_value, USER_VALUE_LEN,
fs->fields[privdata->cur_field]);
ui_show_keyboard(app, privdata->user_value, USER_VALUE_LEN,
text_input_done_callback);
} else if (input.type == InputTypeShort && input.key == InputKeyDown) {
privdata->cur_field = (privdata->cur_field+1) % fs->numfields;
} else if (input.type == InputTypeShort && input.key == InputKeyUp) {
if (privdata->cur_field == 0)
privdata->cur_field = fs->numfields-1;
if(privdata->user_value == NULL) privdata->user_value = malloc(USER_VALUE_LEN);
field_to_string(privdata->user_value, USER_VALUE_LEN, fs->fields[privdata->cur_field]);
ui_show_keyboard(app, privdata->user_value, USER_VALUE_LEN, text_input_done_callback);
} else if(input.type == InputTypeShort && input.key == InputKeyDown) {
privdata->cur_field = (privdata->cur_field + 1) % fs->numfields;
} else if(input.type == InputTypeShort && input.key == InputKeyUp) {
if(privdata->cur_field == 0)
privdata->cur_field = fs->numfields - 1;
else
privdata->cur_field--;
} else if (input.type == InputTypeShort && input.key == InputKeyRight) {
increment_current_field(app,1);
} else if (input.type == InputTypeShort && input.key == InputKeyLeft) {
increment_current_field(app,-1);
} else if (input.type == InputTypeRepeat && input.key == InputKeyRight) {
} else if(input.type == InputTypeShort && input.key == InputKeyRight) {
increment_current_field(app, 1);
} else if(input.type == InputTypeShort && input.key == InputKeyLeft) {
increment_current_field(app, -1);
} else if(input.type == InputTypeRepeat && input.key == InputKeyRight) {
// The reason why we don't use a large increment directly
// is that certain field types only support +1 -1 increments.
int times = 10;
while(times--) increment_current_field(app,1);
} else if (input.type == InputTypeRepeat && input.key == InputKeyLeft) {
while(times--) increment_current_field(app, 1);
} else if(input.type == InputTypeRepeat && input.key == InputKeyLeft) {
int times = 10;
while(times--) increment_current_field(app,-1);
} else if (input.type == InputTypeLong && input.key == InputKeyOk) {
while(times--) increment_current_field(app, -1);
} else if(input.type == InputTypeLong && input.key == InputKeyOk) {
// Build the message in a fresh raw buffer.
if (privdata->decoder->build_message) {
RawSamplesBuffer *rs = raw_samples_alloc();
privdata->decoder->build_message(rs,privdata->fieldset);
if(privdata->decoder->build_message) {
RawSamplesBuffer* rs = raw_samples_alloc();
privdata->decoder->build_message(rs, privdata->fieldset);
app->signal_decoded = false; // So that the new signal will be
// accepted as the current signal.
scan_for_signal(app,rs);
// accepted as the current signal.
scan_for_signal(app, rs);
raw_samples_free(rs);
ui_show_alert(app,"Done: press back key",3000);
ui_show_alert(app, "Done: press back key", 3000);
}
}
}
/* Handle input for the build message view. */
void process_input_build_message(ProtoViewApp *app, InputEvent input) {
BuildViewPrivData *privdata = app->view_privdata;
if (privdata->decoder)
process_input_set_fields(app,input);
void process_input_build_message(ProtoViewApp* app, InputEvent input) {
BuildViewPrivData* privdata = app->view_privdata;
if(privdata->decoder)
process_input_set_fields(app, input);
else
process_input_select_decoder(app,input);
process_input_select_decoder(app, input);
}
/* Enter view callback. */
void view_enter_build_message(ProtoViewApp *app) {
BuildViewPrivData *privdata = app->view_privdata;
void view_enter_build_message(ProtoViewApp* app) {
BuildViewPrivData* privdata = app->view_privdata;
// When we enter the view, the current decoder is just set to zero.
// Seek the next valid if needed.
if (Decoders[privdata->cur_decoder]->get_fields == NULL) {
if(Decoders[privdata->cur_decoder]->get_fields == NULL) {
select_next_decoder(app);
}
// However if there is currently a decoded message, and the
// decoder of such message supports message building, let's
// select it.
if (app->signal_decoded &&
app->msg_info->decoder->get_fields &&
app->msg_info->decoder->build_message)
{
while(Decoders[privdata->cur_decoder] != app->msg_info->decoder)
select_next_decoder(app);
if(app->signal_decoded && app->msg_info->decoder->get_fields &&
app->msg_info->decoder->build_message) {
while(Decoders[privdata->cur_decoder] != app->msg_info->decoder) select_next_decoder(app);
}
}
/* Called on exit for cleanup. */
void view_exit_build_message(ProtoViewApp *app) {
BuildViewPrivData *privdata = app->view_privdata;
if (privdata->fieldset) fieldset_free(privdata->fieldset);
if (privdata->user_value) free(privdata->user_value);
void view_exit_build_message(ProtoViewApp* app) {
BuildViewPrivData* privdata = app->view_privdata;
if(privdata->fieldset) fieldset_free(privdata->fieldset);
if(privdata->user_value) free(privdata->user_value);
}

45
applications/plugins/protoview/view_direct_sampling.c
View File

@@ -7,47 +7,46 @@
/* Read directly from the G0 CC1101 pin, and draw a black or white
* dot depending on the level. */
void render_view_direct_sampling(Canvas *const canvas, ProtoViewApp *app) {
if (!app->direct_sampling_enabled) {
void render_view_direct_sampling(Canvas* const canvas, ProtoViewApp* app) {
if(!app->direct_sampling_enabled) {
canvas_set_font(canvas, FontSecondary);
canvas_draw_str(canvas,2,9,"Direct sampling is a special");
canvas_draw_str(canvas,2,18,"mode that displays the signal");
canvas_draw_str(canvas,2,27,"captured in real time. Like in");
canvas_draw_str(canvas,2,36,"a old CRT TV. It's very slow.");
canvas_draw_str(canvas,2,45,"Can crash your Flipper.");
canvas_draw_str(canvas, 2, 9, "Direct sampling is a special");
canvas_draw_str(canvas, 2, 18, "mode that displays the signal");
canvas_draw_str(canvas, 2, 27, "captured in real time. Like in");
canvas_draw_str(canvas, 2, 36, "a old CRT TV. It's very slow.");
canvas_draw_str(canvas, 2, 45, "Can crash your Flipper.");
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas,14,60,"To enable press OK");
canvas_draw_str(canvas, 14, 60, "To enable press OK");
return;
}
for (int y = 0; y < 64; y++) {
for (int x = 0; x < 128; x++) {
for(int y = 0; y < 64; y++) {
for(int x = 0; x < 128; x++) {
bool level = furi_hal_gpio_read(&gpio_cc1101_g0);
if (level) canvas_draw_dot(canvas,x,y);
if(level) canvas_draw_dot(canvas, x, y);
/* Busy loop: this is a terrible approach as it blocks
* everything else, but for now it's the best we can do
* to obtain direct data with some spacing. */
uint32_t x = 250; while(x--);
uint32_t x = 250;
while(x--)
;
}
}
canvas_set_font(canvas, FontSecondary);
canvas_draw_str_with_border(canvas,36,60,"Direct sampling",
ColorWhite,ColorBlack);
canvas_draw_str_with_border(canvas, 36, 60, "Direct sampling", ColorWhite, ColorBlack);
}
/* Handle input */
void process_input_direct_sampling(ProtoViewApp *app, InputEvent input) {
if (input.type == InputTypePress && input.key == InputKeyOk) {
void process_input_direct_sampling(ProtoViewApp* app, InputEvent input) {
if(input.type == InputTypePress && input.key == InputKeyOk) {
app->direct_sampling_enabled = !app->direct_sampling_enabled;
}
}
/* Enter view. Stop the subghz thread to prevent access as we read
* the CC1101 data directly. */
void view_enter_direct_sampling(ProtoViewApp *app) {
if (app->txrx->txrx_state == TxRxStateRx &&
!app->txrx->debug_timer_sampling)
{
void view_enter_direct_sampling(ProtoViewApp* app) {
if(app->txrx->txrx_state == TxRxStateRx && !app->txrx->debug_timer_sampling) {
subghz_worker_stop(app->txrx->worker);
} else {
raw_sampling_worker_stop(app);
@@ -55,10 +54,8 @@ void view_enter_direct_sampling(ProtoViewApp *app) {
}
/* Exit view. Restore the subghz thread. */
void view_exit_direct_sampling(ProtoViewApp *app) {
if (app->txrx->txrx_state == TxRxStateRx &&
!app->txrx->debug_timer_sampling)
{
void view_exit_direct_sampling(ProtoViewApp* app) {
if(app->txrx->txrx_state == TxRxStateRx && !app->txrx->debug_timer_sampling) {
subghz_worker_start(app->txrx->worker);
} else {
raw_sampling_worker_start(app);

211
applications/plugins/protoview/view_info.c
View File

@@ -20,31 +20,29 @@ typedef struct {
* so that the user can see what they are saving. With left/right
* you can move to next rows. Here we store where we are. */
uint32_t signal_display_start_row;
char *filename;
char* filename;
uint8_t cur_info_page; // Info page to display. Useful when there are
// too many fields populated by the decoder that
// a single page is not enough.
// too many fields populated by the decoder that
// a single page is not enough.
} InfoViewPrivData;
/* Draw the text label and value of the specified info field at x,y. */
static void render_info_field(Canvas *const canvas,
ProtoViewField *f, uint8_t x, uint8_t y)
{
static void render_info_field(Canvas* const canvas, ProtoViewField* f, uint8_t x, uint8_t y) {
char buf[64];
char strval[32];
field_to_string(strval,sizeof(strval),f);
snprintf(buf,sizeof(buf),"%s: %s", f->name, strval);
field_to_string(strval, sizeof(strval), f);
snprintf(buf, sizeof(buf), "%s: %s", f->name, strval);
canvas_set_font(canvas, FontSecondary);
canvas_draw_str(canvas, x, y, buf);
}
/* Render the view with the detected message information. */
#define INFO_LINES_PER_PAGE 5
static void render_subview_main(Canvas *const canvas, ProtoViewApp *app) {
InfoViewPrivData *privdata = app->view_privdata;
uint8_t pages = (app->msg_info->fieldset->numfields
+(INFO_LINES_PER_PAGE-1)) / INFO_LINES_PER_PAGE;
static void render_subview_main(Canvas* const canvas, ProtoViewApp* app) {
InfoViewPrivData* privdata = app->view_privdata;
uint8_t pages =
(app->msg_info->fieldset->numfields + (INFO_LINES_PER_PAGE - 1)) / INFO_LINES_PER_PAGE;
privdata->cur_info_page %= pages;
uint8_t current_page = privdata->cur_info_page;
char buf[32];
@@ -53,9 +51,9 @@ static void render_subview_main(Canvas *const canvas, ProtoViewApp *app) {
canvas_set_font(canvas, FontPrimary);
uint8_t y = 8, lineheight = 10;
if (pages > 1) {
snprintf(buf,sizeof(buf),"%s %u/%u", app->msg_info->decoder->name,
current_page+1, pages);
if(pages > 1) {
snprintf(
buf, sizeof(buf), "%s %u/%u", app->msg_info->decoder->name, current_page + 1, pages);
canvas_draw_str(canvas, 0, y, buf);
} else {
canvas_draw_str(canvas, 0, y, app->msg_info->decoder->name);
@@ -64,26 +62,30 @@ static void render_subview_main(Canvas *const canvas, ProtoViewApp *app) {
/* Draw the info fields. */
uint8_t max_lines = INFO_LINES_PER_PAGE;
uint32_t j = current_page*max_lines;
while (j < app->msg_info->fieldset->numfields) {
render_info_field(canvas,app->msg_info->fieldset->fields[j++],0,y);
uint32_t j = current_page * max_lines;
while(j < app->msg_info->fieldset->numfields) {
render_info_field(canvas, app->msg_info->fieldset->fields[j++], 0, y);
y += lineheight;
if (--max_lines == 0) break;
if(--max_lines == 0) break;
}
/* Draw a vertical "save" label. Temporary solution, to switch to
* something better ASAP. */
y = 37;
lineheight = 7;
canvas_draw_str(canvas, 119, y, "s"); y += lineheight;
canvas_draw_str(canvas, 119, y, "a"); y += lineheight;
canvas_draw_str(canvas, 119, y, "v"); y += lineheight;
canvas_draw_str(canvas, 119, y, "e"); y += lineheight;
canvas_draw_str(canvas, 119, y, "s");
y += lineheight;
canvas_draw_str(canvas, 119, y, "a");
y += lineheight;
canvas_draw_str(canvas, 119, y, "v");
y += lineheight;
canvas_draw_str(canvas, 119, y, "e");
y += lineheight;
}
/* Render view with save option. */
static void render_subview_save(Canvas *const canvas, ProtoViewApp *app) {
InfoViewPrivData *privdata = app->view_privdata;
static void render_subview_save(Canvas* const canvas, ProtoViewApp* app) {
InfoViewPrivData* privdata = app->view_privdata;
/* Display our signal in digital form: here we don't show the
* signal with the exact timing of the received samples, but as it
@@ -92,21 +94,20 @@ static void render_subview_save(Canvas *const canvas, ProtoViewApp *app) {
uint8_t rowheight = 11;
uint8_t bitwidth = 4;
uint8_t bitheight = 5;
uint32_t idx = privdata->signal_display_start_row * (128/4);
uint32_t idx = privdata->signal_display_start_row * (128 / 4);
bool prevbit = false;
for (uint8_t y = bitheight+12; y <= rows*rowheight; y += rowheight) {
for (uint8_t x = 0; x < 128; x += 4) {
bool bit = bitmap_get(app->msg_info->bits,
app->msg_info->bits_bytes,idx);
uint8_t prevy = y + prevbit*(bitheight*-1) - 1;
uint8_t thisy = y + bit*(bitheight*-1) - 1;
canvas_draw_line(canvas,x,prevy,x,thisy);
canvas_draw_line(canvas,x,thisy,x+bitwidth-1,thisy);
for(uint8_t y = bitheight + 12; y <= rows * rowheight; y += rowheight) {
for(uint8_t x = 0; x < 128; x += 4) {
bool bit = bitmap_get(app->msg_info->bits, app->msg_info->bits_bytes, idx);
uint8_t prevy = y + prevbit * (bitheight * -1) - 1;
uint8_t thisy = y + bit * (bitheight * -1) - 1;
canvas_draw_line(canvas, x, prevy, x, thisy);
canvas_draw_line(canvas, x, thisy, x + bitwidth - 1, thisy);
prevbit = bit;
if (idx >= app->msg_info->pulses_count) {
if(idx >= app->msg_info->pulses_count) {
canvas_set_color(canvas, ColorWhite);
canvas_draw_dot(canvas, x+1,thisy);
canvas_draw_dot(canvas, x+3,thisy);
canvas_draw_dot(canvas, x + 1, thisy);
canvas_draw_dot(canvas, x + 3, thisy);
canvas_set_color(canvas, ColorBlack);
}
idx++; // Draw next bit
@@ -118,28 +119,32 @@ static void render_subview_save(Canvas *const canvas, ProtoViewApp *app) {
}
/* Render the selected subview of this view. */
void render_view_info(Canvas *const canvas, ProtoViewApp *app) {
if (app->signal_decoded == false) {
void render_view_info(Canvas* const canvas, ProtoViewApp* app) {
if(app->signal_decoded == false) {
canvas_set_font(canvas, FontSecondary);
canvas_draw_str(canvas, 30,36,"No signal decoded");
canvas_draw_str(canvas, 30, 36, "No signal decoded");
return;
}
ui_show_available_subviews(canvas,app,SubViewInfoLast);
ui_show_available_subviews(canvas, app, SubViewInfoLast);
switch(app->current_subview[app->current_view]) {
case SubViewInfoMain: render_subview_main(canvas,app); break;
case SubViewInfoSave: render_subview_save(canvas,app); break;
case SubViewInfoMain:
render_subview_main(canvas, app);
break;
case SubViewInfoSave:
render_subview_save(canvas, app);
break;
}
}
/* The user typed the file name. Let's save it and remove the keyboard
* view. */
static void text_input_done_callback(void* context) {
ProtoViewApp *app = context;
InfoViewPrivData *privdata = app->view_privdata;
ProtoViewApp* app = context;
InfoViewPrivData* privdata = app->view_privdata;
FuriString *save_path = furi_string_alloc_printf(
"%s/%s.sub", EXT_PATH("subghz"), privdata->filename);
FuriString* save_path =
furi_string_alloc_printf("%s/%s.sub", EXT_PATH("subghz"), privdata->filename);
save_signal(app, furi_string_get_cstr(save_path));
furi_string_free(save_path);
@@ -151,22 +156,22 @@ static void text_input_done_callback(void* context) {
/* Replace all the occurrences of character c1 with c2 in the specified
* string. */
void str_replace(char *buf, char c1, char c2) {
char *p = buf;
void str_replace(char* buf, char c1, char c2) {
char* p = buf;
while(*p) {
if (*p == c1) *p = c2;
if(*p == c1) *p = c2;
p++;
}
}
/* Set a random filename the user can edit. */
void set_signal_random_filename(ProtoViewApp *app, char *buf, size_t buflen) {
void set_signal_random_filename(ProtoViewApp* app, char* buf, size_t buflen) {
char suffix[6];
set_random_name(suffix,sizeof(suffix));
snprintf(buf,buflen,"%.10s-%s-%d",app->msg_info->decoder->name,suffix,rand()%1000);
str_replace(buf,' ','_');
str_replace(buf,'-','_');
str_replace(buf,'/','_');
set_random_name(suffix, sizeof(suffix));
snprintf(buf, buflen, "%.10s-%s-%d", app->msg_info->decoder->name, suffix, rand() % 1000);
str_replace(buf, ' ', '_');
str_replace(buf, '-', '_');
str_replace(buf, '/', '_');
}
/* ========================== Signal transmission =========================== */
@@ -180,20 +185,20 @@ typedef enum {
SendSignalEndTransmission
} SendSignalState;
#define PROTOVIEW_SENDSIGNAL_START_GAP 10000 /* microseconds. */
#define PROTOVIEW_SENDSIGNAL_END_GAP 10000 /* microseconds. */
#define PROTOVIEW_SENDSIGNAL_START_GAP 10000 /* microseconds. */
#define PROTOVIEW_SENDSIGNAL_END_GAP 10000 /* microseconds. */
typedef struct {
SendSignalState state; // Current state.
uint32_t curpos; // Current bit position of data to send.
ProtoViewApp *app; // App reference.
SendSignalState state; // Current state.
uint32_t curpos; // Current bit position of data to send.
ProtoViewApp* app; // App reference.
uint32_t start_gap_dur; // Gap to send at the start.
uint32_t end_gap_dur; // Gap to send at the end.
uint32_t end_gap_dur; // Gap to send at the end.
} SendSignalCtx;
/* Setup the state context for the callback responsible to feed data
* to the subghz async tx system. */
static void send_signal_init(SendSignalCtx *ss, ProtoViewApp *app) {
static void send_signal_init(SendSignalCtx* ss, ProtoViewApp* app) {
ss->state = SendSignalSendStartGap;
ss->curpos = 0;
ss->app = app;
@@ -214,27 +219,26 @@ static void send_signal_init(SendSignalCtx *ss, ProtoViewApp *app) {
* message we are, in ss->curoff. We also send a start and end gap in order
* to make sure the transmission is clear.
*/
LevelDuration radio_tx_feed_data(void *ctx) {
SendSignalCtx *ss = ctx;
LevelDuration radio_tx_feed_data(void* ctx) {
SendSignalCtx* ss = ctx;
/* Send start gap. */
if (ss->state == SendSignalSendStartGap) {
if(ss->state == SendSignalSendStartGap) {
ss->state = SendSignalSendBits;
return level_duration_make(0,ss->start_gap_dur);
return level_duration_make(0, ss->start_gap_dur);
}
/* Send data. */
if (ss->state == SendSignalSendBits) {
if(ss->state == SendSignalSendBits) {
uint32_t dur = 0, j;
uint32_t level = 0;
/* Let's see how many consecutive bits we have with the same
* level. */
for (j = 0; ss->curpos+j < ss->app->msg_info->pulses_count; j++) {
uint32_t l = bitmap_get(ss->app->msg_info->bits,
ss->app->msg_info->bits_bytes,
ss->curpos+j);
if (j == 0) {
for(j = 0; ss->curpos + j < ss->app->msg_info->pulses_count; j++) {
uint32_t l =
bitmap_get(ss->app->msg_info->bits, ss->app->msg_info->bits_bytes, ss->curpos + j);
if(j == 0) {
/* At the first bit of this sequence, we store the
* level of the sequence. */
level = l;
@@ -244,22 +248,21 @@ LevelDuration radio_tx_feed_data(void *ctx) {
/* As long as the level is the same, we update the duration.
* Otherwise stop the loop and return this sample. */
if (l != level) break;
if(l != level) break;
dur += ss->app->msg_info->short_pulse_dur;
}
ss->curpos += j;
/* If this was the last set of bits, change the state to
* send the final gap. */
if (ss->curpos >= ss->app->msg_info->pulses_count)
ss->state = SendSignalSendEndGap;
if(ss->curpos >= ss->app->msg_info->pulses_count) ss->state = SendSignalSendEndGap;
return level_duration_make(level, dur);
}
/* Send end gap. */
if (ss->state == SendSignalSendEndGap) {
if(ss->state == SendSignalSendEndGap) {
ss->state = SendSignalEndTransmission;
return level_duration_make(0,ss->end_gap_dur);
return level_duration_make(0, ss->end_gap_dur);
}
/* End transmission. Here state is guaranteed
@@ -268,7 +271,7 @@ LevelDuration radio_tx_feed_data(void *ctx) {
}
/* Vibrate and produce a click sound when a signal is sent. */
void notify_signal_sent(ProtoViewApp *app) {
void notify_signal_sent(ProtoViewApp* app) {
static const NotificationSequence sent_seq = {
&message_blue_255,
&message_vibro_on,
@@ -277,59 +280,53 @@ void notify_signal_sent(ProtoViewApp *app) {
&message_sound_off,
&message_vibro_off,
&message_blue_0,
NULL
};
NULL};
notification_message(app->notification, &sent_seq);
}
/* Handle input for the info view. */
void process_input_info(ProtoViewApp *app, InputEvent input) {
void process_input_info(ProtoViewApp* app, InputEvent input) {
/* If we don't have a decoded signal, we don't allow to go up/down
* in the subviews: they are only useful when a loaded signal. */
if (app->signal_decoded &&
ui_process_subview_updown(app,input,SubViewInfoLast)) return;
if(app->signal_decoded && ui_process_subview_updown(app, input, SubViewInfoLast)) return;
InfoViewPrivData *privdata = app->view_privdata;
InfoViewPrivData* privdata = app->view_privdata;
int subview = ui_get_current_subview(app);
/* Main subview. */
if (subview == SubViewInfoMain) {
if (input.type == InputTypeLong && input.key == InputKeyOk) {
if(subview == SubViewInfoMain) {
if(input.type == InputTypeLong && input.key == InputKeyOk) {
/* Reset the current sample to capture the next. */
reset_current_signal(app);
} else if (input.type == InputTypeShort && input.key == InputKeyOk) {
} else if(input.type == InputTypeShort && input.key == InputKeyOk) {
/* Show next info page. */
privdata->cur_info_page++;
}
} else if (subview == SubViewInfoSave) {
/* Save subview. */
if (input.type == InputTypePress && input.key == InputKeyRight) {
} else if(subview == SubViewInfoSave) {
/* Save subview. */
if(input.type == InputTypePress && input.key == InputKeyRight) {
privdata->signal_display_start_row++;
} else if (input.type == InputTypePress && input.key == InputKeyLeft) {
if (privdata->signal_display_start_row != 0)
privdata->signal_display_start_row--;
} else if (input.type == InputTypeLong && input.key == InputKeyOk)
{
} else if(input.type == InputTypePress && input.key == InputKeyLeft) {
if(privdata->signal_display_start_row != 0) privdata->signal_display_start_row--;
} else if(input.type == InputTypeLong && input.key == InputKeyOk) {
// We have have the buffer already allocated, in case the
// user aborted with BACK a previous saving.
if (privdata->filename == NULL)
privdata->filename = malloc(SAVE_FILENAME_LEN);
set_signal_random_filename(app,privdata->filename,SAVE_FILENAME_LEN);
ui_show_keyboard(app, privdata->filename, SAVE_FILENAME_LEN,
text_input_done_callback);
} else if (input.type == InputTypeShort && input.key == InputKeyOk) {
if(privdata->filename == NULL) privdata->filename = malloc(SAVE_FILENAME_LEN);
set_signal_random_filename(app, privdata->filename, SAVE_FILENAME_LEN);
ui_show_keyboard(app, privdata->filename, SAVE_FILENAME_LEN, text_input_done_callback);
} else if(input.type == InputTypeShort && input.key == InputKeyOk) {
SendSignalCtx send_state;
send_signal_init(&send_state,app);
radio_tx_signal(app,radio_tx_feed_data,&send_state);
send_signal_init(&send_state, app);
radio_tx_signal(app, radio_tx_feed_data, &send_state);
notify_signal_sent(app);
}
}
}
/* Called on view exit. */
void view_exit_info(ProtoViewApp *app) {
InfoViewPrivData *privdata = app->view_privdata;
void view_exit_info(ProtoViewApp* app) {
InfoViewPrivData* privdata = app->view_privdata;
// When the user aborts the keyboard input, we are left with the
// filename buffer allocated.
if (privdata->filename) free(privdata->filename);
if(privdata->filename) free(privdata->filename);
}

76
applications/plugins/protoview/view_raw_signal.c
View File

@@ -12,7 +12,7 @@
*
* The 'idx' argument is the first sample to render in the circular
* buffer. */
void render_signal(ProtoViewApp *app, Canvas *const canvas, RawSamplesBuffer *buf, uint32_t idx) {
void render_signal(ProtoViewApp* app, Canvas* const canvas, RawSamplesBuffer* buf, uint32_t idx) {
canvas_set_color(canvas, ColorBlack);
int rows = 8;
@@ -20,31 +20,29 @@ void render_signal(ProtoViewApp *app, Canvas *const canvas, RawSamplesBuffer *bu
uint32_t start_idx = idx;
bool level = 0;
uint32_t dur = 0, sample_num = 0;
for (int row = 0; row < rows ; row++) {
for (int x = 0; x < 128; x++) {
int y = 3 + row*8;
if (dur < time_per_pixel/2) {
for(int row = 0; row < rows; row++) {
for(int x = 0; x < 128; x++) {
int y = 3 + row * 8;
if(dur < time_per_pixel / 2) {
/* Get more data. */
raw_samples_get(buf, idx++, &level, &dur);
sample_num++;
}
canvas_draw_line(canvas, x,y,x,y-(level*3));
canvas_draw_line(canvas, x, y, x, y - (level * 3));
/* Write a small triangle under the last sample detected. */
if (app->signal_bestlen != 0 &&
sample_num+start_idx == app->signal_bestlen+1)
{
canvas_draw_dot(canvas,x,y+2);
canvas_draw_dot(canvas,x-1,y+3);
canvas_draw_dot(canvas,x,y+3);
canvas_draw_dot(canvas,x+1,y+3);
if(app->signal_bestlen != 0 && sample_num + start_idx == app->signal_bestlen + 1) {
canvas_draw_dot(canvas, x, y + 2);
canvas_draw_dot(canvas, x - 1, y + 3);
canvas_draw_dot(canvas, x, y + 3);
canvas_draw_dot(canvas, x + 1, y + 3);
sample_num++; /* Make sure we don't mark the next, too. */
}
/* Remove from the current level duration the time we
* just plot. */
if (dur > time_per_pixel)
if(dur > time_per_pixel)
dur -= time_per_pixel;
else
dur = 0;
@@ -53,61 +51,63 @@ void render_signal(ProtoViewApp *app, Canvas *const canvas, RawSamplesBuffer *bu
}
/* Raw pulses rendering. This is our default view. */
void render_view_raw_pulses(Canvas *const canvas, ProtoViewApp *app) {
void render_view_raw_pulses(Canvas* const canvas, ProtoViewApp* app) {
/* Show signal. */
render_signal(app, canvas, DetectedSamples, app->signal_offset);
/* Show signal information. */
char buf[64];
snprintf(buf,sizeof(buf),"%luus",
(unsigned long)DetectedSamples->short_pulse_dur);
snprintf(buf, sizeof(buf), "%luus", (unsigned long)DetectedSamples->short_pulse_dur);
canvas_set_font(canvas, FontSecondary);
canvas_draw_str_with_border(canvas, 97, 63, buf, ColorWhite, ColorBlack);
if (app->signal_decoded) {
if(app->signal_decoded) {
canvas_set_font(canvas, FontPrimary);
canvas_draw_str_with_border(canvas, 1, 61, app->msg_info->decoder->name, ColorWhite, ColorBlack);
canvas_draw_str_with_border(
canvas, 1, 61, app->msg_info->decoder->name, ColorWhite, ColorBlack);
}
}
/* Handle input for the raw pulses view. */
void process_input_raw_pulses(ProtoViewApp *app, InputEvent input) {
if (input.type == InputTypeRepeat) {
void process_input_raw_pulses(ProtoViewApp* app, InputEvent input) {
if(input.type == InputTypeRepeat) {
/* Handle panning of the signal window. Long pressing
* right will show successive samples, long pressing left
* previous samples. */
if (input.key == InputKeyRight) app->signal_offset++;
else if (input.key == InputKeyLeft) app->signal_offset--;
} else if (input.type == InputTypeLong) {
if (input.key == InputKeyOk) {
if(input.key == InputKeyRight)
app->signal_offset++;
else if(input.key == InputKeyLeft)
app->signal_offset--;
} else if(input.type == InputTypeLong) {
if(input.key == InputKeyOk) {
/* Reset the current sample to capture the next. */
reset_current_signal(app);
}
} else if (input.type == InputTypeShort) {
if (input.key == InputKeyOk) {
} else if(input.type == InputTypeShort) {
if(input.key == InputKeyOk) {
app->signal_offset = 0;
adjust_raw_view_scale(app,DetectedSamples->short_pulse_dur);
} else if (input.key == InputKeyDown) {
adjust_raw_view_scale(app, DetectedSamples->short_pulse_dur);
} else if(input.key == InputKeyDown) {
/* Rescaling. The set becomes finer under 50us per pixel. */
uint32_t scale_step = app->us_scale >= 50 ? 50 : 10;
if (app->us_scale < 500) app->us_scale += scale_step;
} else if (input.key == InputKeyUp) {
if(app->us_scale < 500) app->us_scale += scale_step;
} else if(input.key == InputKeyUp) {
uint32_t scale_step = app->us_scale > 50 ? 50 : 10;
if (app->us_scale > 10) app->us_scale -= scale_step;
if(app->us_scale > 10) app->us_scale -= scale_step;
}
}
}
/* Adjust raw view scale depending on short pulse duration. */
void adjust_raw_view_scale(ProtoViewApp *app, uint32_t short_pulse_dur) {
if (short_pulse_dur == 0)
void adjust_raw_view_scale(ProtoViewApp* app, uint32_t short_pulse_dur) {
if(short_pulse_dur == 0)
app->us_scale = PROTOVIEW_RAW_VIEW_DEFAULT_SCALE;
else if (short_pulse_dur < 75)
else if(short_pulse_dur < 75)
app->us_scale = 10;
else if (short_pulse_dur < 145)
else if(short_pulse_dur < 145)
app->us_scale = 30;
else if (short_pulse_dur < 400)
else if(short_pulse_dur < 400)
app->us_scale = 100;
else if (short_pulse_dur < 1000)
else if(short_pulse_dur < 1000)
app->us_scale = 200;
else
app->us_scale = PROTOVIEW_RAW_VIEW_DEFAULT_SCALE;

74
applications/plugins/protoview/view_settings.c
View File

@@ -6,30 +6,30 @@
/* Renders a single view with frequency and modulation setting. However
* this are logically two different views, and only one of the settings
* will be highlighted. */
void render_view_settings(Canvas *const canvas, ProtoViewApp *app) {
void render_view_settings(Canvas* const canvas, ProtoViewApp* app) {
canvas_set_font(canvas, FontPrimary);
if (app->current_view == ViewFrequencySettings)
canvas_draw_str_with_border(canvas,1,10,"Frequency",ColorWhite,ColorBlack);
if(app->current_view == ViewFrequencySettings)
canvas_draw_str_with_border(canvas, 1, 10, "Frequency", ColorWhite, ColorBlack);
else
canvas_draw_str(canvas,1,10,"Frequency");
canvas_draw_str(canvas, 1, 10, "Frequency");
if (app->current_view == ViewModulationSettings)
canvas_draw_str_with_border(canvas,70,10,"Modulation",ColorWhite,ColorBlack);
if(app->current_view == ViewModulationSettings)
canvas_draw_str_with_border(canvas, 70, 10, "Modulation", ColorWhite, ColorBlack);
else
canvas_draw_str(canvas,70,10,"Modulation");
canvas_draw_str(canvas, 70, 10, "Modulation");
canvas_set_font(canvas, FontSecondary);
canvas_draw_str(canvas,10,61,"Use up and down to modify");
canvas_draw_str(canvas, 10, 61, "Use up and down to modify");
if (app->txrx->debug_timer_sampling)
canvas_draw_str(canvas,3,52,"(DEBUG timer sampling is ON)");
if(app->txrx->debug_timer_sampling)
canvas_draw_str(canvas, 3, 52, "(DEBUG timer sampling is ON)");
/* Show frequency. We can use big numbers font since it's just a number. */
if (app->current_view == ViewFrequencySettings) {
if(app->current_view == ViewFrequencySettings) {
char buf[16];
snprintf(buf,sizeof(buf),"%.2f",(double)app->frequency/1000000);
snprintf(buf, sizeof(buf), "%.2f", (double)app->frequency / 1000000);
canvas_set_font(canvas, FontBigNumbers);
canvas_draw_str(canvas, 30, 40, buf);
} else if (app->current_view == ViewModulationSettings) {
} else if(app->current_view == ViewModulationSettings) {
int current = app->modulation;
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas, 33, 39, ProtoViewModulations[current].name);
@@ -37,13 +37,13 @@ void render_view_settings(Canvas *const canvas, ProtoViewApp *app) {
}
/* Handle input for the settings view. */
void process_input_settings(ProtoViewApp *app, InputEvent input) {
if (input.type == InputTypeLong && input.key == InputKeyOk) {
void process_input_settings(ProtoViewApp* app, InputEvent input) {
if(input.type == InputTypeLong && input.key == InputKeyOk) {
/* Long pressing to OK sets the default frequency and
* modulation. */
app->frequency = subghz_setting_get_default_frequency(app->setting);
app->modulation = 0;
} else if (0 && input.type == InputTypeLong && input.key == InputKeyDown) {
} else if(0 && input.type == InputTypeLong && input.key == InputKeyDown) {
/* Long pressing to down switches between normal and debug
* timer sampling mode. NOTE: this feature is disabled for users,
* only useful for devs (if useful at all). */
@@ -55,42 +55,40 @@ void process_input_settings(ProtoViewApp *app, InputEvent input) {
app->txrx->debug_timer_sampling = !app->txrx->debug_timer_sampling;
radio_begin(app);
radio_rx(app);
} else if (input.type == InputTypePress &&
(input.key != InputKeyDown || input.key != InputKeyUp))
{
} else if(input.type == InputTypePress && (input.key != InputKeyDown || input.key != InputKeyUp)) {
/* Handle up and down to change frequency or modulation. */
if (app->current_view == ViewFrequencySettings) {
if(app->current_view == ViewFrequencySettings) {
size_t curidx = 0, i;
size_t count = subghz_setting_get_frequency_count(app->setting);
/* Scan the list of frequencies to check for the index of the
* currently set frequency. */
for(i = 0; i < count; i++) {
uint32_t freq = subghz_setting_get_frequency(app->setting,i);
if (freq == app->frequency) {
uint32_t freq = subghz_setting_get_frequency(app->setting, i);
if(freq == app->frequency) {
curidx = i;
break;
}
}
if (i == count) return; /* Should never happen. */
if(i == count) return; /* Should never happen. */
if (input.key == InputKeyUp) {
curidx = curidx == 0 ? count-1 : curidx-1;
} else if (input.key == InputKeyDown) {
curidx = (curidx+1) % count;
if(input.key == InputKeyUp) {
curidx = curidx == 0 ? count - 1 : curidx - 1;
} else if(input.key == InputKeyDown) {
curidx = (curidx + 1) % count;
} else {
return;
}
app->frequency = subghz_setting_get_frequency(app->setting,curidx);
} else if (app->current_view == ViewModulationSettings) {
app->frequency = subghz_setting_get_frequency(app->setting, curidx);
} else if(app->current_view == ViewModulationSettings) {
uint32_t count = 0;
uint32_t modid = app->modulation;
while(ProtoViewModulations[count].name != NULL) count++;
if (input.key == InputKeyUp) {
modid = modid == 0 ? count-1 : modid-1;
} else if (input.key == InputKeyDown) {
modid = (modid+1) % count;
if(input.key == InputKeyUp) {
modid = modid == 0 ? count - 1 : modid - 1;
} else if(input.key == InputKeyDown) {
modid = (modid + 1) % count;
} else {
return;
}
@@ -106,9 +104,13 @@ void process_input_settings(ProtoViewApp *app, InputEvent input) {
/* When the user switches to some other view, if they changed the parameters
* we need to restart the radio with the right frequency and modulation. */
void view_exit_settings(ProtoViewApp *app) {
if (app->txrx->freq_mod_changed) {
FURI_LOG_E(TAG, "Setting view, setting frequency/modulation to %lu %s", app->frequency, ProtoViewModulations[app->modulation].name);
void view_exit_settings(ProtoViewApp* app) {
if(app->txrx->freq_mod_changed) {
FURI_LOG_E(
TAG,
"Setting view, setting frequency/modulation to %lu %s",
app->frequency,
ProtoViewModulations[app->modulation].name);
radio_rx_end(app);
radio_begin(app);
radio_rx(app);

2
applications/plugins/tama_p1/hal.c
View File

@@ -40,7 +40,7 @@ static void tama_p1_hal_log(log_level_t level, char* buff, ...) {
va_list args;
va_start(args, buff);
furi_string_cat_vprintf(string, buff, args);
va_end(args);
va_end(args);
switch(level) {
case LOG_ERROR:

1
applications/plugins/tama_p1/tama.h
View File

@@ -13,7 +13,6 @@
#define STATE_FILE_VERSION 2
#define TAMA_SAVE_PATH EXT_PATH("tama_p1/save.bin")
typedef struct {
FuriThread* thread;
hal_t hal;

145
applications/plugins/tama_p1/tama_p1.c
View File

@@ -52,7 +52,6 @@ static void tama_p1_draw_callback(Canvas* const canvas, void* cb_ctx) {
uint16_t lcd_icon_lower_left = lcd_matrix_left;
uint16_t lcd_icon_spacing_horiz =
(lcd_matrix_scaled_width - (4 * TAMA_LCD_ICON_SIZE)) / 3 + TAMA_LCD_ICON_SIZE;
uint16_t y = lcd_matrix_top;
for(uint8_t row = 0; row < 16; ++row) {
@@ -71,7 +70,7 @@ static void tama_p1_draw_callback(Canvas* const canvas, void* cb_ctx) {
// Start drawing icons
uint8_t lcd_icons = g_ctx->icons;
// Draw top icons
y = lcd_icon_upper_top;
// y = 64 - TAMA_LCD_ICON_SIZE;
@@ -114,135 +113,134 @@ static void tama_p1_update_timer_callback(FuriMessageQueue* event_queue) {
TamaEvent event = {.type = EventTypeTick};
furi_message_queue_put(event_queue, &event, 0);
}
static void tama_p1_load_state() {
state_t *state;
static void tama_p1_load_state() {
state_t* state;
uint8_t buf[4];
bool error = false;
bool error = false;
state = tamalib_get_state();
Storage* storage = furi_record_open(RECORD_STORAGE);
File* file = storage_file_alloc(storage);
if(storage_file_open(file, TAMA_SAVE_PATH, FSAM_READ, FSOM_OPEN_EXISTING)) {
storage_file_read(file, &buf, 4);
if (buf[0] != (uint8_t) STATE_FILE_MAGIC[0] || buf[1] != (uint8_t) STATE_FILE_MAGIC[1] ||
buf[2] != (uint8_t) STATE_FILE_MAGIC[2] || buf[3] != (uint8_t) STATE_FILE_MAGIC[3]) {
Storage* storage = furi_record_open(RECORD_STORAGE);
File* file = storage_file_alloc(storage);
if(storage_file_open(file, TAMA_SAVE_PATH, FSAM_READ, FSOM_OPEN_EXISTING)) {
storage_file_read(file, &buf, 4);
if(buf[0] != (uint8_t)STATE_FILE_MAGIC[0] || buf[1] != (uint8_t)STATE_FILE_MAGIC[1] ||
buf[2] != (uint8_t)STATE_FILE_MAGIC[2] || buf[3] != (uint8_t)STATE_FILE_MAGIC[3]) {
FURI_LOG_E(TAG, "FATAL: Wrong state file magic in \"%s\" !\n", TAMA_SAVE_PATH);
error = true;
}
storage_file_read(file, &buf, 1);
if (buf[0] != STATE_FILE_VERSION) {
storage_file_read(file, &buf, 1);
if(buf[0] != STATE_FILE_VERSION) {
FURI_LOG_E(TAG, "FATAL: Unsupported version");
error = true;
}
if (!error) {
if(!error) {
FURI_LOG_D(TAG, "Reading save.bin");
storage_file_read(file, &buf, 2);
*(state->pc) = buf[0] | ((buf[1] & 0x1F) << 8);
storage_file_read(file, &buf, 2);
*(state->x) = buf[0] | ((buf[1] & 0xF) << 8);
storage_file_read(file, &buf, 2);
*(state->pc) = buf[0] | ((buf[1] & 0x1F) << 8);
storage_file_read(file, &buf, 2);
*(state->y) = buf[0] | ((buf[1] & 0xF) << 8);
storage_file_read(file, &buf, 2);
*(state->x) = buf[0] | ((buf[1] & 0xF) << 8);
storage_file_read(file, &buf, 1);
*(state->a) = buf[0] & 0xF;
storage_file_read(file, &buf, 2);
*(state->y) = buf[0] | ((buf[1] & 0xF) << 8);
storage_file_read(file, &buf, 1);
*(state->b) = buf[0] & 0xF;
storage_file_read(file, &buf, 1);
*(state->a) = buf[0] & 0xF;
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
*(state->b) = buf[0] & 0xF;
storage_file_read(file, &buf, 1);
*(state->np) = buf[0] & 0x1F;
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
*(state->sp) = buf[0];
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
*(state->flags) = buf[0] & 0xF;
storage_file_read(file, &buf, 4);
storage_file_read(file, &buf, 4);
*(state->tick_counter) = buf[0] | (buf[1] << 8) | (buf[2] << 16) | (buf[3] << 24);
storage_file_read(file, &buf, 4);
*(state->clk_timer_timestamp) = buf[0] | (buf[1] << 8) | (buf[2] << 16) | (buf[3] << 24);
storage_file_read(file, &buf, 4);
*(state->clk_timer_timestamp) = buf[0] | (buf[1] << 8) | (buf[2] << 16) |
(buf[3] << 24);
storage_file_read(file, &buf, 4);
*(state->prog_timer_timestamp) = buf[0] | (buf[1] << 8) | (buf[2] << 16) | (buf[3] << 24);
storage_file_read(file, &buf, 4);
*(state->prog_timer_timestamp) = buf[0] | (buf[1] << 8) | (buf[2] << 16) |
(buf[3] << 24);
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
*(state->prog_timer_enabled) = buf[0] & 0x1;
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
*(state->prog_timer_data) = buf[0];
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
*(state->prog_timer_rld) = buf[0];
storage_file_read(file, &buf, 4);
storage_file_read(file, &buf, 4);
*(state->call_depth) = buf[0] | (buf[1] << 8) | (buf[2] << 16) | (buf[3] << 24);
FURI_LOG_D(TAG, "Restoring Interupts");
for (uint32_t i = 0; i < INT_SLOT_NUM; i++) {
storage_file_read(file, &buf, 1);
for(uint32_t i = 0; i < INT_SLOT_NUM; i++) {
storage_file_read(file, &buf, 1);
state->interrupts[i].factor_flag_reg = buf[0] & 0xF;
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
state->interrupts[i].mask_reg = buf[0] & 0xF;
storage_file_read(file, &buf, 1);
storage_file_read(file, &buf, 1);
state->interrupts[i].triggered = buf[0] & 0x1;
}
/* First 640 half bytes correspond to the RAM */
FURI_LOG_D(TAG, "Restoring RAM");
for (uint32_t i = 0; i < MEM_RAM_SIZE; i++) {
storage_file_read(file, &buf, 1);
for(uint32_t i = 0; i < MEM_RAM_SIZE; i++) {
storage_file_read(file, &buf, 1);
SET_RAM_MEMORY(state->memory, i + MEM_RAM_ADDR, buf[0] & 0xF);
}
/* I/Os are from 0xF00 to 0xF7F */
FURI_LOG_D(TAG, "Restoring I/O");
for (uint32_t i = 0; i < MEM_IO_SIZE; i++) {
storage_file_read(file, &buf, 1);
for(uint32_t i = 0; i < MEM_IO_SIZE; i++) {
storage_file_read(file, &buf, 1);
SET_IO_MEMORY(state->memory, i + MEM_IO_ADDR, buf[0] & 0xF);
}
FURI_LOG_D(TAG, "Refreshing Hardware");
tamalib_refresh_hw();
}
}
FURI_LOG_D(TAG, "Refreshing Hardware");
tamalib_refresh_hw();
}
}
storage_file_close(file);
storage_file_free(file);
furi_record_close(RECORD_STORAGE);
furi_record_close(RECORD_STORAGE);
}
static void tama_p1_save_state() {
// Saving state
FURI_LOG_D(TAG, "Saving Gamestate");
uint8_t buf[4];
state_t *state;
state_t* state;
uint32_t offset = 0;
state = tamalib_get_state();
Storage* storage = furi_record_open(RECORD_STORAGE);
File* file = storage_file_alloc(storage);
Storage* storage = furi_record_open(RECORD_STORAGE);
File* file = storage_file_alloc(storage);
if(storage_file_open(file, TAMA_SAVE_PATH, FSAM_WRITE, FSOM_CREATE_ALWAYS)) {
buf[0] = (uint8_t) STATE_FILE_MAGIC[0];
buf[1] = (uint8_t) STATE_FILE_MAGIC[1];
buf[2] = (uint8_t) STATE_FILE_MAGIC[2];
buf[3] = (uint8_t) STATE_FILE_MAGIC[3];
buf[0] = (uint8_t)STATE_FILE_MAGIC[0];
buf[1] = (uint8_t)STATE_FILE_MAGIC[1];
buf[2] = (uint8_t)STATE_FILE_MAGIC[2];
buf[3] = (uint8_t)STATE_FILE_MAGIC[3];
offset += storage_file_write(file, &buf, sizeof(buf));
buf[0] = STATE_FILE_VERSION & 0xFF;
offset += storage_file_write(file, &buf, 1);
buf[0] = *(state->pc) & 0xFF;
buf[1] = (*(state->pc) >> 8) & 0x1F;
offset += storage_file_write(file, &buf, 2);
@@ -303,7 +301,7 @@ static void tama_p1_save_state() {
buf[3] = (*(state->call_depth) >> 24) & 0xFF;
offset += storage_file_write(file, &buf, sizeof(buf));
for (uint32_t i = 0; i < INT_SLOT_NUM; i++) {
for(uint32_t i = 0; i < INT_SLOT_NUM; i++) {
buf[0] = state->interrupts[i].factor_flag_reg & 0xF;
offset += storage_file_write(file, &buf, 1);
@@ -315,17 +313,17 @@ static void tama_p1_save_state() {
}
/* First 640 half bytes correspond to the RAM */
for (uint32_t i = 0; i < MEM_RAM_SIZE; i++) {
for(uint32_t i = 0; i < MEM_RAM_SIZE; i++) {
buf[0] = GET_RAM_MEMORY(state->memory, i + MEM_RAM_ADDR) & 0xF;
offset += storage_file_write(file, &buf, 1);
}
/* I/Os are from 0xF00 to 0xF7F */
for (uint32_t i = 0; i < MEM_IO_SIZE; i++) {
for(uint32_t i = 0; i < MEM_IO_SIZE; i++) {
buf[0] = GET_IO_MEMORY(state->memory, i + MEM_IO_ADDR) & 0xF;
offset += storage_file_write(file, &buf, 1);
}
}
}
storage_file_close(file);
storage_file_free(file);
furi_record_close(RECORD_STORAGE);
@@ -333,7 +331,6 @@ static void tama_p1_save_state() {
FURI_LOG_D(TAG, "Finished Writing %lu", offset);
}
static int32_t tama_p1_worker(void* context) {
bool running = true;
FuriMutex* mutex = context;
@@ -357,8 +354,6 @@ static int32_t tama_p1_worker(void* context) {
furi_mutex_release(mutex);
return 0;
}
static void tama_p1_init(TamaApp* const ctx) {
g_ctx = ctx;
@@ -485,9 +480,9 @@ int32_t tama_p1_app(void* p) {
tamalib_set_button(BTN_MIDDLE, tama_btn_state);
} else if(event.input.key == InputKeyRight) {
tamalib_set_button(BTN_RIGHT, tama_btn_state);
} else if(event.input.key == InputKeyDown && event.input.type == InputTypeShort) {
} else if(event.input.key == InputKeyDown && event.input.type == InputTypeShort) {
// TODO: pause or fast-forward tamagotchi
tama_p1_save_state();
tama_p1_save_state();
} else if(event.input.key == InputKeyUp) { // mute tamagotchi
tamalib_set_button(BTN_LEFT, tama_btn_state);
tamalib_set_button(BTN_RIGHT, tama_btn_state);
@@ -500,7 +495,7 @@ int32_t tama_p1_app(void* p) {
furi_timer_stop(timer);
running = false;
tama_p1_save_state();
tama_p1_save_state();
}
}

35
applications/services/desktop/animations/animation_manager.c
View File

@@ -145,7 +145,8 @@ void animation_manager_check_blocking_process(AnimationManager* animation_manage
const StorageAnimationManifestInfo* manifest_info =
animation_storage_get_meta(animation_manager->current_animation);
bool valid = animation_manager_is_valid_idle_animation(manifest_info, &stats, XTREME_SETTINGS()->unlock_anims);
bool valid = animation_manager_is_valid_idle_animation(
manifest_info, &stats, XTREME_SETTINGS()->unlock_anims);
if(!valid) {
animation_manager_start_new_idle(animation_manager);
@@ -201,8 +202,10 @@ static void animation_manager_start_new_idle(AnimationManager* animation_manager
animation_storage_get_bubble_animation(animation_manager->current_animation);
animation_manager->state = AnimationManagerStateIdle;
XtremeSettings* xtreme_settings = XTREME_SETTINGS();
int32_t duration = (xtreme_settings->cycle_anims == 0) ? (bubble_animation->duration) : (xtreme_settings->cycle_anims);
furi_timer_start(animation_manager->idle_animation_timer, (duration > 0) ? (duration * 1000) : 0);
int32_t duration = (xtreme_settings->cycle_anims == 0) ? (bubble_animation->duration) :
(xtreme_settings->cycle_anims);
furi_timer_start(
animation_manager->idle_animation_timer, (duration > 0) ? (duration * 1000) : 0);
}
static bool animation_manager_check_blocking(AnimationManager* animation_manager) {
@@ -355,7 +358,7 @@ static bool animation_manager_is_valid_idle_animation(
result = (sd_status == FSE_NOT_READY);
}
if (!unlock) {
if(!unlock) {
if((stats->butthurt < info->min_butthurt) || (stats->butthurt > info->max_butthurt)) {
result = false;
}
@@ -370,8 +373,9 @@ static bool animation_manager_is_valid_idle_animation(
static StorageAnimation*
animation_manager_select_idle_animation(AnimationManager* animation_manager) {
const char* old_animation_name = NULL;
if (animation_manager->current_animation) {
old_animation_name = animation_storage_get_meta(animation_manager->current_animation)->name;
if(animation_manager->current_animation) {
old_animation_name =
animation_storage_get_meta(animation_manager->current_animation)->name;
}
StorageAnimationList_t animation_list;
@@ -391,8 +395,8 @@ static StorageAnimation*
animation_storage_get_meta(storage_animation);
bool valid = animation_manager_is_valid_idle_animation(manifest_info, &stats, unlock);
if (old_animation_name != NULL) {
if (strcmp(manifest_info->name, old_animation_name) == 0) {
if(old_animation_name != NULL) {
if(strcmp(manifest_info->name, old_animation_name) == 0) {
valid = false;
}
}
@@ -512,7 +516,8 @@ void animation_manager_load_and_continue_animation(AnimationManager* animation_m
furi_record_close(RECORD_DOLPHIN);
const StorageAnimationManifestInfo* manifest_info =
animation_storage_get_meta(restore_animation);
bool valid = animation_manager_is_valid_idle_animation(manifest_info, &stats, XTREME_SETTINGS()->unlock_anims);
bool valid = animation_manager_is_valid_idle_animation(
manifest_info, &stats, XTREME_SETTINGS()->unlock_anims);
if(valid) {
animation_manager_replace_current_animation(
animation_manager, restore_animation);
@@ -523,12 +528,16 @@ void animation_manager_load_and_continue_animation(AnimationManager* animation_m
animation_manager->idle_animation_timer,
animation_manager->freezed_animation_time_left);
} else {
const BubbleAnimation* bubble_animation = animation_storage_get_bubble_animation(
animation_manager->current_animation);
const BubbleAnimation* bubble_animation =
animation_storage_get_bubble_animation(
animation_manager->current_animation);
XtremeSettings* xtreme_settings = XTREME_SETTINGS();
int32_t duration = (xtreme_settings->cycle_anims == 0) ? (bubble_animation->duration) : (xtreme_settings->cycle_anims);
int32_t duration = (xtreme_settings->cycle_anims == 0) ?
(bubble_animation->duration) :
(xtreme_settings->cycle_anims);
furi_timer_start(
animation_manager->idle_animation_timer, (duration > 0) ? (duration * 1000) : 0);
animation_manager->idle_animation_timer,
(duration > 0) ? (duration * 1000) : 0);
}
}
} else {

9
applications/services/desktop/animations/animation_storage.c
View File

@@ -35,18 +35,18 @@ void animation_handler_select_manifest() {
FuriString* anim_dir = furi_string_alloc();
FuriString* manifest = furi_string_alloc();
bool use_asset_pack = xtreme_settings->asset_pack[0] != '\0';
if (use_asset_pack) {
if(use_asset_pack) {
furi_string_printf(anim_dir, "%s/%s/Anims", PACKS_DIR, xtreme_settings->asset_pack);
furi_string_printf(manifest, "%s/manifest.txt", furi_string_get_cstr(anim_dir));
Storage* storage = furi_record_open(RECORD_STORAGE);
if (storage_common_stat(storage, furi_string_get_cstr(manifest), NULL) == FSE_OK) {
if(storage_common_stat(storage, furi_string_get_cstr(manifest), NULL) == FSE_OK) {
FURI_LOG_I(TAG, "Custom Manifest selected");
} else {
use_asset_pack = false;
}
furi_record_close(RECORD_STORAGE);
}
if (!use_asset_pack) {
if(!use_asset_pack) {
furi_string_set(anim_dir, BASE_ANIMATION_DIR);
if(xtreme_settings->nsfw_mode) {
furi_string_cat_str(anim_dir, "/nsfw");
@@ -58,7 +58,8 @@ void animation_handler_select_manifest() {
furi_string_printf(manifest, "%s/manifest.txt", furi_string_get_cstr(anim_dir));
}
strlcpy(ANIMATION_DIR, furi_string_get_cstr(anim_dir), sizeof(ANIMATION_DIR));
strlcpy(ANIMATION_MANIFEST_FILE, furi_string_get_cstr(manifest), sizeof(ANIMATION_MANIFEST_FILE));
strlcpy(
ANIMATION_MANIFEST_FILE, furi_string_get_cstr(manifest), sizeof(ANIMATION_MANIFEST_FILE));
furi_string_free(manifest);
furi_string_free(anim_dir);
}

2
applications/services/desktop/views/desktop_view_lock_menu.c
View File

@@ -68,7 +68,7 @@ void desktop_lock_menu_draw_callback(Canvas* canvas, void* model) {
str = "Set PIN + Off";
}
} else if(i == DesktopLockMenuIndexXtremeSettings) {
str = "Xtreme Settings";
str = "Xtreme Settings";
}
if(str) //-V547

7
applications/services/dolphin/helpers/dolphin_state.c
View File

@@ -15,9 +15,10 @@
#define DOLPHIN_STATE_HEADER_MAGIC 0xD0
#define DOLPHIN_STATE_HEADER_VERSION 0x01
const int DOLPHIN_LEVELS[DOLPHIN_LEVEL_COUNT] = {100, 200, 300, 450, 600, 750, 950, 1150, 1350, 1600,
1850, 2100, 2400, 2700, 3000, 3350, 3700, 4050, 4450, 4850,
5250, 5700, 6150, 6600, 7100, 7600, 8100, 8650, 9200};
const int DOLPHIN_LEVELS[DOLPHIN_LEVEL_COUNT] = {100, 200, 300, 450, 600, 750, 950, 1150,
1350, 1600, 1850, 2100, 2400, 2700, 3000, 3350,
3700, 4050, 4450, 4850, 5250, 5700, 6150, 6600,
7100, 7600, 8100, 8650, 9200};
#define BUTTHURT_MAX 14
#define BUTTHURT_MIN 0

9
applications/services/power/power_service/power.c
View File

@@ -26,7 +26,7 @@ void power_draw_battery_callback(Canvas* canvas, void* context) {
snprintf(batteryPercentile, sizeof(batteryPercentile), "%d", power->info.charge);
if((battery_style == BatteryStylePercent) &&
(power->state !=
(power->state !=
PowerStateCharging)) { //if display battery percentage, black background white text
canvas_set_font(canvas, FontBatteryPercent);
canvas_set_color(canvas, ColorBlack);
@@ -36,7 +36,7 @@ void power_draw_battery_callback(Canvas* canvas, void* context) {
} else if(
(battery_style == BatteryStyleInvertedPercent) &&
(power->state !=
PowerStateCharging)) { //if display inverted percentage, white background black text
PowerStateCharging)) { //if display inverted percentage, white background black text
canvas_set_font(canvas, FontBatteryPercent);
canvas_set_color(canvas, ColorBlack);
canvas_draw_str_aligned(canvas, 11, 4, AlignCenter, AlignCenter, batteryPercentile);
@@ -74,7 +74,7 @@ void power_draw_battery_callback(Canvas* canvas, void* context) {
(battery_style == BatteryStyleBarPercent) &&
(power->state != PowerStateCharging) && // Default bar display with percentage
(power->info.voltage_battery_charging >=
4.2)) { // not looking nice with low voltage indicator
4.2)) { // not looking nice with low voltage indicator
canvas_set_font(canvas, FontBatteryPercent);
// align charge dispaly value with digits to draw
@@ -145,8 +145,7 @@ void power_draw_battery_callback(Canvas* canvas, void* context) {
if(power->state == PowerStateCharging) {
canvas_set_bitmap_mode(canvas, 1);
// TODO: replace -1 magic for uint8_t with re-framing
if(battery_style == BatteryStylePercent ||
battery_style == BatteryStyleBarPercent) {
if(battery_style == BatteryStylePercent || battery_style == BatteryStyleBarPercent) {
canvas_set_color(canvas, ColorBlack);
canvas_draw_box(canvas, 1, 1, 22, 6);
canvas_draw_icon(canvas, 2, -1, &I_Charging_lightning_9x10);

19
applications/settings/about/about.c
View File

@@ -222,9 +222,9 @@ static void draw_battery(Canvas* canvas, PowerInfo* info, int x, int y) {
snprintf(header, sizeof(header), "Charged!");
}
if (!strcmp(value, "")) {
if(!strcmp(value, "")) {
canvas_draw_str_aligned(canvas, x + 92, y + 14, AlignCenter, AlignCenter, header);
} else if (!strcmp(header, "")) {
} else if(!strcmp(header, "")) {
canvas_draw_str_aligned(canvas, x + 92, y + 14, AlignCenter, AlignCenter, value);
} else {
canvas_draw_str_aligned(canvas, x + 92, y + 9, AlignCenter, AlignCenter, header);
@@ -298,7 +298,6 @@ const AboutDialogScreen about_screens[] = {
const int about_screens_count = sizeof(about_screens) / sizeof(AboutDialogScreen);
int32_t about_settings_app(void* p) {
bool battery_info = false;
if(p && strlen(p) && !strcmp(p, "batt")) {
@@ -324,24 +323,19 @@ int32_t about_settings_app(void* p) {
DialogMessageButton screen_result;
// draw empty screen to prevent menu flickering
view_dispatcher_add_view(
view_dispatcher, battery_info_index, battery_view);
view_dispatcher_add_view(view_dispatcher, battery_info_index, battery_view);
view_dispatcher_add_view(
view_dispatcher, empty_screen_index, empty_screen_get_view(empty_screen));
view_dispatcher_attach_to_gui(view_dispatcher, gui, ViewDispatcherTypeFullscreen);
screen_index = -1 + !battery_info;
while(screen_index > -2) {
if (screen_index == -1) {
if (!battery_info) {
if(screen_index == -1) {
if(!battery_info) {
break;
}
with_view_model(
battery_view,
PowerInfo * model,
{ power_get_info(power, model); },
true);
battery_view, PowerInfo * model, { power_get_info(power, model); }, true);
view_dispatcher_switch_to_view(view_dispatcher, battery_info_index);
furi_semaphore_acquire(semaphore, 2000);
} else {
@@ -360,7 +354,6 @@ int32_t about_settings_app(void* p) {
screen_index = -2;
}
}
}
dialog_message_free(message);

2
applications/settings/dolphin_passport/passport.c
View File

@@ -67,7 +67,7 @@ static void render_callback(Canvas* canvas, void* _ctx) {
uint32_t xp_need = dolphin_state_xp_to_levelup(stats->icounter);
uint32_t xp_above_last_levelup = dolphin_state_xp_above_last_levelup(stats->icounter);
uint32_t xp_levelup = 0;
if (ctx->progress_total) {
if(ctx->progress_total) {
xp_levelup = xp_need + stats->icounter;
} else {
xp_levelup = xp_need + xp_above_last_levelup;

76
applications/settings/xtreme_settings/scenes/xtreme_settings_scene_start.c
View File

@@ -15,8 +15,12 @@ static void xtreme_settings_scene_start_base_graphics_changed(VariableItem* item
static void xtreme_settings_scene_start_asset_pack_changed(VariableItem* item) {
XtremeSettingsApp* app = variable_item_get_context(item);
uint8_t index = variable_item_get_current_value_index(item);
variable_item_set_current_value_text(item, index == 0 ? "OFF" : *asset_packs_get(app->asset_packs, index - 1));
strlcpy(XTREME_SETTINGS()->asset_pack, index == 0 ? "" : *asset_packs_get(app->asset_packs, index - 1), MAX_PACK_NAME_LEN);
variable_item_set_current_value_text(
item, index == 0 ? "OFF" : *asset_packs_get(app->asset_packs, index - 1));
strlcpy(
XTREME_SETTINGS()->asset_pack,
index == 0 ? "" : *asset_packs_get(app->asset_packs, index - 1),
MAX_PACK_NAME_LEN);
app->settings_changed = true;
app->assets_changed = true;
}
@@ -33,8 +37,20 @@ static void xtreme_settings_scene_start_anim_speed_changed(VariableItem* item) {
app->settings_changed = true;
}
const char* const cycle_anims_names[] =
{"OFF", "Meta.txt", "30 S", "1 M", "5 M", "10 M", "15 M", "30 M", "1 H", "2 H", "6 H", "12 H", "24 H"};
const char* const cycle_anims_names[] = {
"OFF",
"Meta.txt",
"30 S",
"1 M",
"5 M",
"10 M",
"15 M",
"30 M",
"1 H",
"2 H",
"6 H",
"12 H",
"24 H"};
const int32_t cycle_anims_values[COUNT_OF(cycle_anims_names)] =
{-1, 0, 30, 60, 300, 600, 900, 1800, 3600, 7200, 21600, 43200, 86400};
static void xtreme_settings_scene_start_cycle_anims_changed(VariableItem* item) {
@@ -62,8 +78,7 @@ const int32_t battery_style_values[COUNT_OF(battery_style_names)] = {
BatteryStyleInvertedPercent,
BatteryStyleRetro3,
BatteryStyleRetro5,
BatteryStyleBarPercent
};
BatteryStyleBarPercent};
static void xtreme_settings_scene_start_battery_style_changed(VariableItem* item) {
XtremeSettingsApp* app = variable_item_get_context(item);
uint8_t index = variable_item_get_current_value_index(item);
@@ -112,7 +127,8 @@ void xtreme_settings_scene_start_on_enter(void* context) {
app->subghz_extend = false;
app->subghz_bypass = false;
if(flipper_format_file_open_existing(subghz_range, "/ext/subghz/assets/extend_range.txt")) {
flipper_format_read_bool(subghz_range, "use_ext_range_at_own_risk", &app->subghz_extend, 1);
flipper_format_read_bool(
subghz_range, "use_ext_range_at_own_risk", &app->subghz_extend, 1);
flipper_format_read_bool(subghz_range, "ignore_default_tx_region", &app->subghz_bypass, 1);
}
flipper_format_free(subghz_range);
@@ -123,14 +139,15 @@ void xtreme_settings_scene_start_on_enter(void* context) {
FileInfo info;
char* name = malloc(MAX_PACK_NAME_LEN);
do {
if (!storage_dir_open(folder, PACKS_DIR)) break;
if(!storage_dir_open(folder, PACKS_DIR)) break;
while(true) {
if (!storage_dir_read(folder, &info, name, MAX_PACK_NAME_LEN)) break;
if(!storage_dir_read(folder, &info, name, MAX_PACK_NAME_LEN)) break;
if(info.flags & FSF_DIRECTORY) {
char* copy = malloc(MAX_PACK_NAME_LEN);
strlcpy(copy, name, MAX_PACK_NAME_LEN);
asset_packs_push_back(app->asset_packs, copy);
if (strcmp(name, xtreme_settings->asset_pack) == 0) current_pack = asset_packs_size(app->asset_packs);
if(strcmp(name, xtreme_settings->asset_pack) == 0)
current_pack = asset_packs_size(app->asset_packs);
}
}
} while(false);
@@ -139,11 +156,7 @@ void xtreme_settings_scene_start_on_enter(void* context) {
furi_record_close(RECORD_STORAGE);
item = variable_item_list_add(
var_item_list,
"Base Graphics",
2,
xtreme_settings_scene_start_base_graphics_changed,
app);
var_item_list, "Base Graphics", 2, xtreme_settings_scene_start_base_graphics_changed, app);
variable_item_set_current_value_index(item, xtreme_settings->nsfw_mode);
variable_item_set_current_value_text(item, xtreme_settings->nsfw_mode ? "NSFW" : "SFW");
@@ -154,7 +167,8 @@ void xtreme_settings_scene_start_on_enter(void* context) {
xtreme_settings_scene_start_asset_pack_changed,
app);
variable_item_set_current_value_index(item, current_pack);
variable_item_set_current_value_text(item, current_pack == 0 ? "OFF" : *asset_packs_get(app->asset_packs, current_pack - 1));
variable_item_set_current_value_text(
item, current_pack == 0 ? "OFF" : *asset_packs_get(app->asset_packs, current_pack - 1));
item = variable_item_list_add(
var_item_list,
@@ -179,11 +193,7 @@ void xtreme_settings_scene_start_on_enter(void* context) {
variable_item_set_current_value_text(item, cycle_anims_names[value_index]);
item = variable_item_list_add(
var_item_list,
"Unlock Anims",
2,
xtreme_settings_scene_start_unlock_anims_changed,
app);
var_item_list, "Unlock Anims", 2, xtreme_settings_scene_start_unlock_anims_changed, app);
variable_item_set_current_value_index(item, xtreme_settings->unlock_anims);
variable_item_set_current_value_text(item, xtreme_settings->unlock_anims ? "ON" : "OFF");
@@ -210,30 +220,18 @@ void xtreme_settings_scene_start_on_enter(void* context) {
variable_item_set_current_value_text(item, level_str);
item = variable_item_list_add(
var_item_list,
"SubGHz Extend",
2,
xtreme_settings_scene_start_subghz_extend_changed,
app);
var_item_list, "SubGHz Extend", 2, xtreme_settings_scene_start_subghz_extend_changed, app);
variable_item_set_current_value_index(item, app->subghz_extend);
variable_item_set_current_value_text(item, app->subghz_extend ? "ON" : "OFF");
item = variable_item_list_add(
var_item_list,
"SubGHz Bypass",
2,
xtreme_settings_scene_start_subghz_bypass_changed,
app);
var_item_list, "SubGHz Bypass", 2, xtreme_settings_scene_start_subghz_bypass_changed, app);
variable_item_set_current_value_index(item, app->subghz_bypass);
variable_item_set_current_value_text(item, app->subghz_bypass ? "ON" : "OFF");
FuriString* version_tag = furi_string_alloc_printf("%s %s", version_get_gitbranchnum(NULL), version_get_builddate(NULL));
item = variable_item_list_add(
var_item_list,
furi_string_get_cstr(version_tag),
0,
NULL,
app);
FuriString* version_tag = furi_string_alloc_printf(
"%s %s", version_get_gitbranchnum(NULL), version_get_builddate(NULL));
item = variable_item_list_add(var_item_list, furi_string_get_cstr(version_tag), 0, NULL, app);
view_dispatcher_switch_to_view(app->view_dispatcher, XtremeSettingsAppViewVarItemList);
}
@@ -248,7 +246,7 @@ bool xtreme_settings_scene_start_on_event(void* context, SceneManagerEvent event
void xtreme_settings_scene_start_on_exit(void* context) {
XtremeSettingsApp* app = context;
asset_packs_it_t it;
for (asset_packs_it(it, app->asset_packs); !asset_packs_end_p(it); asset_packs_next(it)) {
for(asset_packs_it(it, app->asset_packs); !asset_packs_end_p(it); asset_packs_next(it)) {
free(*asset_packs_cref(it));
}
asset_packs_clear(app->asset_packs);

207
applications/settings/xtreme_settings/xtreme_assets.c
View File

@@ -5,94 +5,158 @@
XtremeAssets* xtreme_assets = NULL;
XtremeAssets* XTREME_ASSETS() {
if (xtreme_assets == NULL) {
if(xtreme_assets == NULL) {
XTREME_ASSETS_LOAD();
}
return xtreme_assets;
}
void XTREME_ASSETS_LOAD() {
if (xtreme_assets != NULL) return;
if(xtreme_assets != NULL) return;
xtreme_assets = malloc(sizeof(XtremeAssets));
XtremeSettings* xtreme_settings = XTREME_SETTINGS();
if (xtreme_settings->nsfw_mode) {
xtreme_assets->I_BLE_Pairing_128x64 = &I_BLE_Pairing_128x64;
xtreme_assets->I_DolphinCommon_56x48 = &I_DolphinCommon_56x48;
xtreme_assets->I_DolphinMafia_115x62 = &I_DolphinMafia_115x62;
xtreme_assets->I_DolphinNice_96x59 = &I_DolphinNice_96x59;
xtreme_assets->I_DolphinWait_61x59 = &I_DolphinWait_61x59;
if(xtreme_settings->nsfw_mode) {
xtreme_assets->I_BLE_Pairing_128x64 = &I_BLE_Pairing_128x64;
xtreme_assets->I_DolphinCommon_56x48 = &I_DolphinCommon_56x48;
xtreme_assets->I_DolphinMafia_115x62 = &I_DolphinMafia_115x62;
xtreme_assets->I_DolphinNice_96x59 = &I_DolphinNice_96x59;
xtreme_assets->I_DolphinWait_61x59 = &I_DolphinWait_61x59;
xtreme_assets->I_iButtonDolphinVerySuccess_108x52 = &I_iButtonDolphinVerySuccess_108x52;
xtreme_assets->I_DolphinReadingSuccess_59x63 = &I_DolphinReadingSuccess_59x63;
xtreme_assets->I_NFC_dolphin_emulation_47x61 = &I_NFC_dolphin_emulation_47x61;
xtreme_assets->I_passport_bad_46x49 = &I_flipper;
xtreme_assets->I_passport_DB = &I_passport_DB;
xtreme_assets->I_passport_happy_46x49 = &I_flipper;
xtreme_assets->I_passport_okay_46x49 = &I_flipper;
xtreme_assets->I_RFIDDolphinReceive_97x61 = &I_RFIDDolphinReceive_97x61;
xtreme_assets->I_RFIDDolphinSend_97x61 = &I_RFIDDolphinSend_97x61;
xtreme_assets->I_RFIDDolphinSuccess_108x57 = &I_RFIDDolphinSuccess_108x57;
xtreme_assets->I_Cry_dolph_55x52 = &I_Cry_dolph_55x52;
xtreme_assets->I_Scanning_123x52 = &I_Scanning_123x52;
xtreme_assets->I_Auth_62x31 = &I_Auth_62x31;
xtreme_assets->I_Connect_me_62x31 = &I_Connect_me_62x31;
xtreme_assets->I_Connected_62x31 = &I_Connected_62x31;
xtreme_assets->I_Error_62x31 = &I_Error_62x31;
xtreme_assets->I_DolphinReadingSuccess_59x63 = &I_DolphinReadingSuccess_59x63;
xtreme_assets->I_NFC_dolphin_emulation_47x61 = &I_NFC_dolphin_emulation_47x61;
xtreme_assets->I_passport_bad_46x49 = &I_flipper;
xtreme_assets->I_passport_DB = &I_passport_DB;
xtreme_assets->I_passport_happy_46x49 = &I_flipper;
xtreme_assets->I_passport_okay_46x49 = &I_flipper;
xtreme_assets->I_RFIDDolphinReceive_97x61 = &I_RFIDDolphinReceive_97x61;
xtreme_assets->I_RFIDDolphinSend_97x61 = &I_RFIDDolphinSend_97x61;
xtreme_assets->I_RFIDDolphinSuccess_108x57 = &I_RFIDDolphinSuccess_108x57;
xtreme_assets->I_Cry_dolph_55x52 = &I_Cry_dolph_55x52;
xtreme_assets->I_Scanning_123x52 = &I_Scanning_123x52;
xtreme_assets->I_Auth_62x31 = &I_Auth_62x31;
xtreme_assets->I_Connect_me_62x31 = &I_Connect_me_62x31;
xtreme_assets->I_Connected_62x31 = &I_Connected_62x31;
xtreme_assets->I_Error_62x31 = &I_Error_62x31;
} else {
xtreme_assets->I_BLE_Pairing_128x64 = &I_BLE_Pairing_128x64_sfw;
xtreme_assets->I_DolphinCommon_56x48 = &I_DolphinCommon_56x48_sfw;
xtreme_assets->I_DolphinMafia_115x62 = &I_DolphinMafia_115x62_sfw;
xtreme_assets->I_DolphinNice_96x59 = &I_DolphinNice_96x59_sfw;
xtreme_assets->I_DolphinWait_61x59 = &I_DolphinWait_61x59_sfw;
xtreme_assets->I_iButtonDolphinVerySuccess_108x52 = &I_iButtonDolphinVerySuccess_108x52_sfw;
xtreme_assets->I_DolphinReadingSuccess_59x63 = &I_DolphinReadingSuccess_59x63_sfw;
xtreme_assets->I_NFC_dolphin_emulation_47x61 = &I_NFC_dolphin_emulation_47x61_sfw;
xtreme_assets->I_passport_bad_46x49 = &I_passport_bad1_46x49_sfw;
xtreme_assets->I_passport_DB = &I_passport_DB_sfw;
xtreme_assets->I_passport_happy_46x49 = &I_passport_happy1_46x49_sfw;
xtreme_assets->I_passport_okay_46x49 = &I_passport_okay1_46x49_sfw;
xtreme_assets->I_RFIDDolphinReceive_97x61 = &I_RFIDDolphinReceive_97x61_sfw;
xtreme_assets->I_RFIDDolphinSend_97x61 = &I_RFIDDolphinSend_97x61_sfw;
xtreme_assets->I_RFIDDolphinSuccess_108x57 = &I_RFIDDolphinSuccess_108x57_sfw;
xtreme_assets->I_Cry_dolph_55x52 = &I_Cry_dolph_55x52_sfw;
xtreme_assets->I_Scanning_123x52 = &I_Scanning_123x52_sfw;
xtreme_assets->I_Auth_62x31 = &I_Auth_62x31_sfw;
xtreme_assets->I_Connect_me_62x31 = &I_Connect_me_62x31_sfw;
xtreme_assets->I_Connected_62x31 = &I_Connected_62x31_sfw;
xtreme_assets->I_Error_62x31 = &I_Error_62x31_sfw;
xtreme_assets->I_BLE_Pairing_128x64 = &I_BLE_Pairing_128x64_sfw;
xtreme_assets->I_DolphinCommon_56x48 = &I_DolphinCommon_56x48_sfw;
xtreme_assets->I_DolphinMafia_115x62 = &I_DolphinMafia_115x62_sfw;
xtreme_assets->I_DolphinNice_96x59 = &I_DolphinNice_96x59_sfw;
xtreme_assets->I_DolphinWait_61x59 = &I_DolphinWait_61x59_sfw;
xtreme_assets->I_iButtonDolphinVerySuccess_108x52 =
&I_iButtonDolphinVerySuccess_108x52_sfw;
xtreme_assets->I_DolphinReadingSuccess_59x63 = &I_DolphinReadingSuccess_59x63_sfw;
xtreme_assets->I_NFC_dolphin_emulation_47x61 = &I_NFC_dolphin_emulation_47x61_sfw;
xtreme_assets->I_passport_bad_46x49 = &I_passport_bad1_46x49_sfw;
xtreme_assets->I_passport_DB = &I_passport_DB_sfw;
xtreme_assets->I_passport_happy_46x49 = &I_passport_happy1_46x49_sfw;
xtreme_assets->I_passport_okay_46x49 = &I_passport_okay1_46x49_sfw;
xtreme_assets->I_RFIDDolphinReceive_97x61 = &I_RFIDDolphinReceive_97x61_sfw;
xtreme_assets->I_RFIDDolphinSend_97x61 = &I_RFIDDolphinSend_97x61_sfw;
xtreme_assets->I_RFIDDolphinSuccess_108x57 = &I_RFIDDolphinSuccess_108x57_sfw;
xtreme_assets->I_Cry_dolph_55x52 = &I_Cry_dolph_55x52_sfw;
xtreme_assets->I_Scanning_123x52 = &I_Scanning_123x52_sfw;
xtreme_assets->I_Auth_62x31 = &I_Auth_62x31_sfw;
xtreme_assets->I_Connect_me_62x31 = &I_Connect_me_62x31_sfw;
xtreme_assets->I_Connected_62x31 = &I_Connected_62x31_sfw;
xtreme_assets->I_Error_62x31 = &I_Error_62x31_sfw;
}
if (xtreme_settings->asset_pack[0] == '\0') return;
if(xtreme_settings->asset_pack[0] == '\0') return;
FileInfo info;
FuriString* path = furi_string_alloc();
const char* pack = xtreme_settings->asset_pack;
furi_string_printf(path, PACKS_DIR "/%s", pack);
Storage* storage = furi_record_open(RECORD_STORAGE);
if (storage_common_stat(storage, furi_string_get_cstr(path), &info) == FSE_OK && info.flags & FSF_DIRECTORY) {
if(storage_common_stat(storage, furi_string_get_cstr(path), &info) == FSE_OK &&
info.flags & FSF_DIRECTORY) {
File* file = storage_file_alloc(storage);
swap_bmx_icon(&xtreme_assets->I_BLE_Pairing_128x64, pack, "BLE/BLE_Pairing_128x64.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_DolphinCommon_56x48, pack, "Dolphin/DolphinCommon_56x48.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_DolphinMafia_115x62, pack, "iButton/DolphinMafia_115x62.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_DolphinNice_96x59, pack, "iButton/DolphinNice_96x59.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_DolphinWait_61x59, pack, "iButton/DolphinWait_61x59.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_iButtonDolphinVerySuccess_108x52, pack, "iButton/iButtonDolphinVerySuccess_108x52.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_DolphinReadingSuccess_59x63, pack, "Infrared/DolphinReadingSuccess_59x63.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_NFC_dolphin_emulation_47x61, pack, "NFC/NFC_dolphin_emulation_47x61.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_passport_bad_46x49, pack, "Passport/passport_bad_46x49.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_passport_DB, pack, "Passport/passport_DB.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_passport_happy_46x49, pack, "Passport/passport_happy_46x49.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_passport_okay_46x49, pack, "Passport/passport_okay_46x49.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_RFIDDolphinReceive_97x61, pack, "RFID/RFIDDolphinReceive_97x61.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_RFIDDolphinSend_97x61, pack, "RFID/RFIDDolphinSend_97x61.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_RFIDDolphinSuccess_108x57, pack, "RFID/RFIDDolphinSuccess_108x57.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Cry_dolph_55x52, pack, "Settings/Cry_dolph_55x52.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Scanning_123x52, pack, "SubGhz/Scanning_123x52.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Auth_62x31, pack, "U2F/Auth_62x31.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Connect_me_62x31, pack, "U2F/Connect_me_62x31.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Connected_62x31, pack, "U2F/Connected_62x31.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Error_62x31, pack, "U2F/Error_62x31.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_BLE_Pairing_128x64, pack, "BLE/BLE_Pairing_128x64.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_DolphinCommon_56x48,
pack,
"Dolphin/DolphinCommon_56x48.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_DolphinMafia_115x62,
pack,
"iButton/DolphinMafia_115x62.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_DolphinNice_96x59, pack, "iButton/DolphinNice_96x59.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_DolphinWait_61x59, pack, "iButton/DolphinWait_61x59.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_iButtonDolphinVerySuccess_108x52,
pack,
"iButton/iButtonDolphinVerySuccess_108x52.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_DolphinReadingSuccess_59x63,
pack,
"Infrared/DolphinReadingSuccess_59x63.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_NFC_dolphin_emulation_47x61,
pack,
"NFC/NFC_dolphin_emulation_47x61.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_passport_bad_46x49,
pack,
"Passport/passport_bad_46x49.bmx",
path,
file);
swap_bmx_icon(&xtreme_assets->I_passport_DB, pack, "Passport/passport_DB.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_passport_happy_46x49,
pack,
"Passport/passport_happy_46x49.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_passport_okay_46x49,
pack,
"Passport/passport_okay_46x49.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_RFIDDolphinReceive_97x61,
pack,
"RFID/RFIDDolphinReceive_97x61.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_RFIDDolphinSend_97x61,
pack,
"RFID/RFIDDolphinSend_97x61.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_RFIDDolphinSuccess_108x57,
pack,
"RFID/RFIDDolphinSuccess_108x57.bmx",
path,
file);
swap_bmx_icon(
&xtreme_assets->I_Cry_dolph_55x52, pack, "Settings/Cry_dolph_55x52.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_Scanning_123x52, pack, "SubGhz/Scanning_123x52.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Auth_62x31, pack, "U2F/Auth_62x31.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_Connect_me_62x31, pack, "U2F/Connect_me_62x31.bmx", path, file);
swap_bmx_icon(
&xtreme_assets->I_Connected_62x31, pack, "U2F/Connected_62x31.bmx", path, file);
swap_bmx_icon(&xtreme_assets->I_Error_62x31, pack, "U2F/Error_62x31.bmx", path, file);
storage_file_free(file);
}
@@ -100,9 +164,14 @@ void XTREME_ASSETS_LOAD() {
furi_string_free(path);
}
void swap_bmx_icon(const Icon** replace, const char* pack, const char* name, FuriString* path, File* file) {
void swap_bmx_icon(
const Icon** replace,
const char* pack,
const char* name,
FuriString* path,
File* file) {
furi_string_printf(path, PACKS_DIR "/%s/Icons/%s", pack, name);
if (storage_file_open(file, furi_string_get_cstr(path), FSAM_READ, FSOM_OPEN_EXISTING)) {
if(storage_file_open(file, furi_string_get_cstr(path), FSAM_READ, FSOM_OPEN_EXISTING)) {
uint64_t size = storage_file_size(file) - 8;
int32_t width, height;
storage_file_read(file, &width, 4);

7
applications/settings/xtreme_settings/xtreme_assets.h
View File

@@ -34,6 +34,11 @@ XtremeAssets* XTREME_ASSETS();
void XTREME_ASSETS_LOAD();
void swap_bmx_icon(const Icon** replace, const char* base, const char* name, FuriString* path, File* file);
void swap_bmx_icon(
const Icon** replace,
const char* base,
const char* name,
FuriString* path,
File* file);
void free_bmx_icon(Icon* icon);

18
applications/settings/xtreme_settings/xtreme_settings.c
View File

@@ -3,17 +3,21 @@
XtremeSettings* xtreme_settings = NULL;
XtremeSettings* XTREME_SETTINGS() {
if (xtreme_settings == NULL) {
if(xtreme_settings == NULL) {
XTREME_SETTINGS_LOAD();
}
return xtreme_settings;
}
bool XTREME_SETTINGS_LOAD() {
if (xtreme_settings == NULL) {
if(xtreme_settings == NULL) {
xtreme_settings = malloc(sizeof(XtremeSettings));
bool loaded = saved_struct_load(
XTREME_SETTINGS_PATH, xtreme_settings, sizeof(XtremeSettings), XTREME_SETTINGS_MAGIC, XTREME_SETTINGS_VERSION);
XTREME_SETTINGS_PATH,
xtreme_settings,
sizeof(XtremeSettings),
XTREME_SETTINGS_MAGIC,
XTREME_SETTINGS_VERSION);
if(!loaded) {
memset(xtreme_settings, 0, sizeof(XtremeSettings));
loaded = XTREME_SETTINGS_SAVE();
@@ -24,9 +28,13 @@ bool XTREME_SETTINGS_LOAD() {
}
bool XTREME_SETTINGS_SAVE() {
if (xtreme_settings == NULL) {
if(xtreme_settings == NULL) {
XTREME_SETTINGS_LOAD();
}
return saved_struct_save(
XTREME_SETTINGS_PATH, xtreme_settings, sizeof(XtremeSettings), XTREME_SETTINGS_MAGIC, XTREME_SETTINGS_VERSION);
XTREME_SETTINGS_PATH,
xtreme_settings,
sizeof(XtremeSettings),
XTREME_SETTINGS_MAGIC,
XTREME_SETTINGS_VERSION);
}

20
applications/settings/xtreme_settings/xtreme_settings_app.c
View File

@@ -15,10 +15,10 @@ static bool xtreme_settings_back_event_callback(void* context) {
furi_assert(context);
XtremeSettingsApp* app = context;
if (app->level_changed) {
if(app->level_changed) {
Dolphin* dolphin = furi_record_open(RECORD_DOLPHIN);
DolphinStats stats = dolphin_stats(dolphin);
if (app->dolphin_level != stats.level) {
if(app->dolphin_level != stats.level) {
int xp = app->dolphin_level > 1 ? dolphin_get_levels()[app->dolphin_level - 2] : 0;
dolphin->state->data.icounter = xp + 1;
dolphin->state->dirty = true;
@@ -27,20 +27,22 @@ static bool xtreme_settings_back_event_callback(void* context) {
furi_record_close(RECORD_DOLPHIN);
}
if (app->subghz_changed) {
if(app->subghz_changed) {
Storage* storage = furi_record_open(RECORD_STORAGE);
FlipperFormat* subghz_range = flipper_format_file_alloc(storage);
if(flipper_format_file_open_existing(subghz_range, "/ext/subghz/assets/extend_range.txt")) {
flipper_format_insert_or_update_bool(subghz_range, "use_ext_range_at_own_risk", &app->subghz_extend, 1);
flipper_format_insert_or_update_bool(subghz_range, "ignore_default_tx_region", &app->subghz_bypass, 1);
flipper_format_insert_or_update_bool(
subghz_range, "use_ext_range_at_own_risk", &app->subghz_extend, 1);
flipper_format_insert_or_update_bool(
subghz_range, "ignore_default_tx_region", &app->subghz_bypass, 1);
}
flipper_format_free(subghz_range);
furi_record_close(RECORD_STORAGE);
}
if (app->settings_changed) {
if(app->settings_changed) {
XTREME_SETTINGS_SAVE();
if (app->assets_changed) {
if(app->assets_changed) {
popup_set_header(app->popup, "Rebooting...", 64, 26, AlignCenter, AlignCenter);
popup_set_text(app->popup, "Swapping assets...", 64, 40, AlignCenter, AlignCenter);
popup_set_callback(app->popup, xtreme_settings_reboot);
@@ -81,9 +83,7 @@ XtremeSettingsApp* xtreme_settings_app_alloc() {
app->popup = popup_alloc();
view_dispatcher_add_view(
app->view_dispatcher,
XtremeSettingsAppViewPopup,
popup_get_view(app->popup));
app->view_dispatcher, XtremeSettingsAppViewPopup, popup_get_view(app->popup));
// Set first scene
scene_manager_next_scene(app->scene_manager, XtremeSettingsAppSceneStart);