unleashed-firmware/applications/dec_hex_converter/dec_hex_converter.c
2022-08-13 17:58:46 +03:00

404 lines
No EOL
15 KiB
C

#include <furi.h>
#include <gui/gui.h>
#include <input/input.h>
#include <stdlib.h>
#define DEC_HEX_CONVERTER_NUMBER_DIGITS 9
#define DEC_HEX_CONVERTER_KEYS 18
#define DEC_HEX_CONVERTER_KEY_DEL 16
// #define DEC_HEX_CONVERTER_KEY_SWAP 17 // actually not used...
#define DEC_HEX_CONVERTER_CHAR_DEL '<'
#define DEC_HEX_CONVERTER_CHAR_SWAP 's'
#define DEC_HEX_CONVERTER_CHAR_MODE '#'
#define DEC_HEX_CONVERTER_CHAR_OVERFLOW '#'
#define DEC_HEX_CONVERTER_KEY_FRAME_MARGIN 3
#define DEC_HEX_CONVERTER_KEY_CHAR_HEIGHT 8
#define DEC_HEX_MAX_SUPORTED_DEC_INT 999999999
typedef enum {
EventTypeKey,
} EventType;
typedef struct {
InputEvent input;
EventType type;
} DecHexConverterEvent;
typedef enum {
ModeDec,
ModeHex,
} Mode;
// setting up one char array next to the other one causes the canvas_draw_str to display both of them
// when addressing the first one if there's no string terminator or similar indicator. Adding a \0 seems
// to work fine to prevent that, so add a final last char outside the size constants (added on init
// and NEVER changed nor referenced again)
//
// (as a reference, canvas_draw_str ends up calling u8g2_DrawStr from u8g2_font.c,
// that finally ends up calling u8g2_draw_string)
typedef struct {
char dec_number[DEC_HEX_CONVERTER_NUMBER_DIGITS + 1];
char hex_number[DEC_HEX_CONVERTER_NUMBER_DIGITS + 1];
Mode mode; // dec / hex
int8_t cursor; // position on keyboard (includes digit letters and other options)
int8_t digit_pos; // current digit on selected mode
} DecHexConverterState;
// move cursor left / right (TODO: implement menu nav in a more "standard" and reusable way?)
void dec_hex_converter_logic_move_cursor_lr(
DecHexConverterState* const dec_hex_converter_state,
int8_t d) {
dec_hex_converter_state->cursor += d;
if(dec_hex_converter_state->cursor > DEC_HEX_CONVERTER_KEYS - 1)
dec_hex_converter_state->cursor = 0;
else if(dec_hex_converter_state->cursor < 0)
dec_hex_converter_state->cursor = DEC_HEX_CONVERTER_KEYS - 1;
// if we're moving left / right to the letters keys on ModeDec just go to the closest available key
if(dec_hex_converter_state->mode == ModeDec) {
if(dec_hex_converter_state->cursor == 10)
dec_hex_converter_state->cursor = 16;
else if(dec_hex_converter_state->cursor == 15)
dec_hex_converter_state->cursor = 9;
}
}
// move cursor up / down; there're two lines, so we basically toggle
void dec_hex_converter_logic_move_cursor_ud(DecHexConverterState* const dec_hex_converter_state) {
if(dec_hex_converter_state->cursor < 9) {
// move to second line ("down")
dec_hex_converter_state->cursor += 9;
// if we're reaching the letter keys while ModeDec, just move left / right for the first available key
if(dec_hex_converter_state->mode == ModeDec &&
(dec_hex_converter_state->cursor >= 10 && dec_hex_converter_state->cursor <= 15)) {
if(dec_hex_converter_state->cursor <= 12)
dec_hex_converter_state->cursor = 9;
else
dec_hex_converter_state->cursor = 16;
}
} else {
// move to first line ("up")
dec_hex_converter_state->cursor -= 9;
}
}
// fetch number from current mode and modifies the destination one, RM dnt stel pls
// (if destination is shorter than the output value, overried with "-" chars or something similar)
void dec_hex_converter_logic_convert_number(DecHexConverterState* const dec_hex_converter_state) {
char* s_ptr;
char* d_ptr;
char dest[DEC_HEX_CONVERTER_NUMBER_DIGITS];
int i = 0; // current index on destination array
if(dec_hex_converter_state->mode == ModeDec) {
// DEC to HEX cannot overflow if they're, at least, the same size
s_ptr = dec_hex_converter_state->dec_number;
d_ptr = dec_hex_converter_state->hex_number;
int a = atoi(s_ptr);
int r;
while(a != 0) {
r = a % 16;
dest[i] = r + (r < 10 ? '0' : ('A' - 10));
a /= 16;
i++;
}
} else {
s_ptr = dec_hex_converter_state->hex_number;
d_ptr = dec_hex_converter_state->dec_number;
int a = strtol(s_ptr, NULL, 16);
if(a > DEC_HEX_MAX_SUPORTED_DEC_INT) {
// draw all "###" if there's an overflow
for(int j = 0; j < DEC_HEX_CONVERTER_NUMBER_DIGITS; j++) {
d_ptr[j] = DEC_HEX_CONVERTER_CHAR_OVERFLOW;
}
return;
} else {
while(a > 0) {
dest[i++] = (a % 10) + '0';
a /= 10;
}
}
}
// dest is reversed, copy to destination pointer and append empty chars at the end
for(int j = 0; j < DEC_HEX_CONVERTER_NUMBER_DIGITS; j++) {
if(i >= 1)
d_ptr[j] = dest[--i];
else
d_ptr[j] = ' ';
}
}
// change from DEC to HEX or HEX to DEC, set the digit_pos to the last position not empty on the destination mode
void dec_hex_converter_logic_swap_mode(DecHexConverterState* const dec_hex_converter_state) {
char* n_ptr;
if(dec_hex_converter_state->mode == ModeDec) {
dec_hex_converter_state->mode = ModeHex;
n_ptr = dec_hex_converter_state->hex_number;
} else {
dec_hex_converter_state->mode = ModeDec;
n_ptr = dec_hex_converter_state->dec_number;
}
dec_hex_converter_state->digit_pos = DEC_HEX_CONVERTER_NUMBER_DIGITS;
for(int i = 0; i < DEC_HEX_CONVERTER_NUMBER_DIGITS; i++) {
if(n_ptr[i] == ' ') {
dec_hex_converter_state->digit_pos = i;
break;
}
}
}
// removes the number on current digit on current mode
static void
dec_hex_converter_logic_del_number(DecHexConverterState* const dec_hex_converter_state) {
if(dec_hex_converter_state->digit_pos > 0) dec_hex_converter_state->digit_pos--;
if(dec_hex_converter_state->mode == ModeDec) {
dec_hex_converter_state->dec_number[dec_hex_converter_state->digit_pos] = ' ';
} else {
dec_hex_converter_state->hex_number[dec_hex_converter_state->digit_pos] = ' ';
}
}
// append a number to the digit on the current mode
static void dec_hex_converter_logic_add_number(
DecHexConverterState* const dec_hex_converter_state,
int8_t number) {
// ignore HEX values on DEC mode (probably button nav will be disabled too, so cannot reach);
// also do not add anything if we're out of bound
if((number > 9 && dec_hex_converter_state->mode == ModeDec) ||
dec_hex_converter_state->digit_pos >= DEC_HEX_CONVERTER_NUMBER_DIGITS)
return;
char* s_ptr;
if(dec_hex_converter_state->mode == ModeDec) {
s_ptr = dec_hex_converter_state->dec_number;
} else {
s_ptr = dec_hex_converter_state->hex_number;
}
if(number < 10) {
s_ptr[dec_hex_converter_state->digit_pos] = number + '0';
} else {
s_ptr[dec_hex_converter_state->digit_pos] = (number - 10) + 'A'; // A-F (HEX only)
}
dec_hex_converter_state->digit_pos++;
}
// ---------------
static void dec_hex_converter_render_callback(Canvas* const canvas, void* ctx) {
const DecHexConverterState* dec_hex_converter_state = acquire_mutex((ValueMutex*)ctx, 25);
if(dec_hex_converter_state == NULL) {
return;
}
canvas_set_color(canvas, ColorBlack);
// DEC
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas, 2, 10, "DEC: ");
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas, 2 + 30, 10, dec_hex_converter_state->dec_number);
// HEX
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas, 2, 10 + 12, "HEX: ");
canvas_set_font(canvas, FontPrimary);
canvas_draw_str(canvas, 2 + 30, 10 + 12, dec_hex_converter_state->hex_number);
// current mode indicator
// char buffer[4];
// snprintf(buffer, sizeof(buffer), "%u", dec_hex_converter_state->digit_pos); // debug: show digit position instead of selected mode
if(dec_hex_converter_state->mode == ModeDec) {
canvas_draw_glyph(canvas, 128 - 10, 10, DEC_HEX_CONVERTER_CHAR_MODE);
} else {
canvas_draw_glyph(canvas, 128 - 10, 10 + 12, DEC_HEX_CONVERTER_CHAR_MODE);
}
// draw the line
canvas_draw_line(canvas, 2, 25, 128 - 3, 25);
// draw the keyboard
uint8_t _x = 5;
uint8_t _y = 25 + 15; // line + 10
for(int i = 0; i < DEC_HEX_CONVERTER_KEYS; i++) {
char g;
if(i < 10)
g = (i + '0');
else if(i < 16)
g = ((i - 10) + 'A');
else if(i == 16)
g = DEC_HEX_CONVERTER_CHAR_DEL; // '<'
else
g = DEC_HEX_CONVERTER_CHAR_SWAP; // 's'
uint8_t g_w = canvas_glyph_width(canvas, g);
// disable letters on DEC mode (but keep the previous width for visual purposes - show "blank keys")
if(dec_hex_converter_state->mode == ModeDec && i > 9 && i < 16) g = ' ';
if(dec_hex_converter_state->cursor == i) {
canvas_draw_box(
canvas,
_x - DEC_HEX_CONVERTER_KEY_FRAME_MARGIN,
_y - (DEC_HEX_CONVERTER_KEY_CHAR_HEIGHT + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN),
DEC_HEX_CONVERTER_KEY_FRAME_MARGIN + g_w + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN,
DEC_HEX_CONVERTER_KEY_CHAR_HEIGHT + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN * 2);
canvas_set_color(canvas, ColorWhite);
canvas_draw_glyph(canvas, _x, _y, g);
canvas_set_color(canvas, ColorBlack);
} else {
canvas_draw_frame(
canvas,
_x - DEC_HEX_CONVERTER_KEY_FRAME_MARGIN,
_y - (DEC_HEX_CONVERTER_KEY_CHAR_HEIGHT + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN),
DEC_HEX_CONVERTER_KEY_FRAME_MARGIN + g_w + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN,
DEC_HEX_CONVERTER_KEY_CHAR_HEIGHT + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN * 2);
canvas_draw_glyph(canvas, _x, _y, g);
}
if(i < 8) {
_x += g_w + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN * 2 + 2;
} else if(i == 8) {
_y += (DEC_HEX_CONVERTER_KEY_CHAR_HEIGHT + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN * 2) + 3;
_x = 7; // some padding at the beginning on second line
} else {
_x += g_w + DEC_HEX_CONVERTER_KEY_FRAME_MARGIN * 2 + 1;
}
}
release_mutex((ValueMutex*)ctx, dec_hex_converter_state);
}
static void
dec_hex_converter_input_callback(InputEvent* input_event, FuriMessageQueue* event_queue) {
furi_assert(event_queue);
DecHexConverterEvent event = {.type = EventTypeKey, .input = *input_event};
furi_message_queue_put(event_queue, &event, FuriWaitForever);
}
static void dec_hex_converter_init(DecHexConverterState* const dec_hex_converter_state) {
dec_hex_converter_state->mode = ModeDec;
dec_hex_converter_state->digit_pos = 0;
dec_hex_converter_state->dec_number[DEC_HEX_CONVERTER_NUMBER_DIGITS] = '\0'; // null terminator
dec_hex_converter_state->hex_number[DEC_HEX_CONVERTER_NUMBER_DIGITS] = '\0'; // null terminator
for(int i = 0; i < DEC_HEX_CONVERTER_NUMBER_DIGITS; i++) {
dec_hex_converter_state->dec_number[i] = ' ';
dec_hex_converter_state->hex_number[i] = ' ';
}
}
// main entry point
int32_t dec_hex_converter_app(void* p) {
UNUSED(p);
// get event queue
FuriMessageQueue* event_queue = furi_message_queue_alloc(8, sizeof(DecHexConverterEvent));
// allocate state
DecHexConverterState* dec_hex_converter_state = malloc(sizeof(DecHexConverterState));
// set mutex for plugin state (different threads can access it)
ValueMutex state_mutex;
if(!init_mutex(&state_mutex, dec_hex_converter_state, sizeof(dec_hex_converter_state))) {
FURI_LOG_E("DecHexConverter", "cannot create mutex\r\n");
furi_message_queue_free(event_queue);
free(dec_hex_converter_state);
return 255;
}
// register callbacks for drawing and input processing
ViewPort* view_port = view_port_alloc();
view_port_draw_callback_set(view_port, dec_hex_converter_render_callback, &state_mutex);
view_port_input_callback_set(view_port, dec_hex_converter_input_callback, event_queue);
// open GUI and register view_port
Gui* gui = furi_record_open(RECORD_GUI);
gui_add_view_port(gui, view_port, GuiLayerFullscreen);
dec_hex_converter_init(dec_hex_converter_state);
// main loop
DecHexConverterEvent event;
for(bool processing = true; processing;) {
FuriStatus event_status = furi_message_queue_get(event_queue, &event, 100);
DecHexConverterState* dec_hex_converter_state =
(DecHexConverterState*)acquire_mutex_block(&state_mutex);
if(event_status == FuriStatusOk) {
// press events
if(event.type == EventTypeKey) {
if(event.input.type == InputTypePress) {
switch(event.input.key) {
default:
break;
case InputKeyUp:
case InputKeyDown:
dec_hex_converter_logic_move_cursor_ud(dec_hex_converter_state);
break;
case InputKeyRight:
dec_hex_converter_logic_move_cursor_lr(dec_hex_converter_state, 1);
break;
case InputKeyLeft:
dec_hex_converter_logic_move_cursor_lr(dec_hex_converter_state, -1);
break;
case InputKeyOk:
if(dec_hex_converter_state->cursor < DEC_HEX_CONVERTER_KEY_DEL) {
// positions from 0 to 15 works as regular numbers (DEC / HEX where applicable)
// (logic won't allow add numbers > 9 on ModeDec)
dec_hex_converter_logic_add_number(
dec_hex_converter_state, dec_hex_converter_state->cursor);
} else if(dec_hex_converter_state->cursor == DEC_HEX_CONVERTER_KEY_DEL) {
// del
dec_hex_converter_logic_del_number(dec_hex_converter_state);
} else {
// swap
dec_hex_converter_logic_swap_mode(dec_hex_converter_state);
}
dec_hex_converter_logic_convert_number(dec_hex_converter_state);
break;
case InputKeyBack:
processing = false;
break;
}
}
}
} else {
// event timeout
}
view_port_update(view_port);
release_mutex(&state_mutex, dec_hex_converter_state);
}
view_port_enabled_set(view_port, false);
gui_remove_view_port(gui, view_port);
furi_record_close(RECORD_GUI);
view_port_free(view_port);
furi_message_queue_free(event_queue);
delete_mutex(&state_mutex);
free(dec_hex_converter_state);
return 0;
}