5439e232cc
* API HAL SPI: refactoring, split into layers, prepare ST HAL separation. API HAL SubGhz: initialize on start. Drivers: add basic cc1101 driver. Update API usage. Debug: increase max debugger port speed. Remove subghz apps. * CC1101: chip status handling. ApiHalSpi: increase SubGhz bus speed to 8mhz. F4: backport subghz initialization. * Api Hal SubGhz: rx path and frequency. CC1101: frequency control. * SubGhz Application: basic tests * SubGhz app: tone and packet test. API HAL SUBGHZ: update configs, add missing bits and pieces.
417 lines
12 KiB
C
417 lines
12 KiB
C
#include <furi.h>
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#include <api-hal.h>
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#include <gui/gui.h>
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#include <stream_buffer.h>
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typedef enum { EventTypeTick, EventTypeKey, EventTypeRx } EventType;
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typedef struct {
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uint8_t dummy;
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} RxEvent;
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typedef struct {
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union {
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InputEvent input;
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RxEvent rx;
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} value;
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EventType type;
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} AppEvent;
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typedef struct {
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uint32_t freq_khz;
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bool on;
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uint8_t customer_id;
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uint32_t em_data;
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bool dirty;
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bool dirty_freq;
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} State;
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static void render_callback(Canvas* canvas, void* ctx) {
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State* state = (State*)acquire_mutex((ValueMutex*)ctx, 25);
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canvas_clear(canvas);
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canvas_set_color(canvas, ColorBlack);
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canvas_set_font(canvas, FontPrimary);
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canvas_draw_str(canvas, 2, 12, "LF RFID");
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canvas_draw_str(canvas, 2, 24, state->on ? "Reading" : "Emulating");
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char buf[30];
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snprintf(buf, sizeof(buf), "%d kHz", (int)state->freq_khz);
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canvas_draw_str(canvas, 2, 36, buf);
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snprintf(buf, sizeof(buf), "%02d:%010ld", state->customer_id, state->em_data);
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canvas_draw_str(canvas, 2, 45, buf);
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release_mutex((ValueMutex*)ctx, state);
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}
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static void input_callback(InputEvent* input_event, void* ctx) {
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osMessageQueueId_t event_queue = ctx;
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AppEvent event;
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event.type = EventTypeKey;
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event.value.input = *input_event;
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osMessageQueuePut(event_queue, &event, 0, 0);
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}
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extern TIM_HandleTypeDef TIM_C;
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void em4100_emulation(uint8_t* data, GpioPin* pin);
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void prepare_data(uint32_t ID, uint32_t VENDOR, uint8_t* data);
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GpioPin debug_0 = {.pin = GPIO_PIN_2, .port = GPIOB};
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GpioPin debug_1 = {.pin = GPIO_PIN_3, .port = GPIOC};
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extern COMP_HandleTypeDef hcomp1;
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typedef struct {
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osMessageQueueId_t event_queue;
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uint32_t prev_dwt;
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int8_t symbol;
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bool center;
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size_t symbol_cnt;
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StreamBufferHandle_t stream_buffer;
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uint8_t* int_buffer;
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} ComparatorCtx;
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void init_comp_ctx(ComparatorCtx* ctx) {
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ctx->prev_dwt = 0;
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ctx->symbol = -1; // init state
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ctx->center = false;
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ctx->symbol_cnt = 0;
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xStreamBufferReset(ctx->stream_buffer);
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for(size_t i = 0; i < 64; i++) {
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ctx->int_buffer[i] = 0;
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}
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}
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void comparator_trigger_callback(void* hcomp, void* comp_ctx) {
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ComparatorCtx* ctx = (ComparatorCtx*)comp_ctx;
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uint32_t dt = (DWT->CYCCNT - ctx->prev_dwt) / (SystemCoreClock / 1000000.0f);
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ctx->prev_dwt = DWT->CYCCNT;
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if(dt < 150) return; // supress noise
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// wait message will be consumed
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if(xStreamBufferBytesAvailable(ctx->stream_buffer) == 64) return;
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gpio_write(&debug_0, true);
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// TOOD F4 and F5 differ
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bool rx_value = get_rfid_in_level();
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if(dt > 384) {
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// change symbol 0->1 or 1->0
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ctx->symbol = rx_value;
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ctx->center = true;
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} else {
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// same symbol as prev or center
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ctx->center = !ctx->center;
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}
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/*
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gpio_write(&debug_1, true);
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delay_us(center ? 10 : 30);
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gpio_write(&debug_1, false);
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*/
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BaseType_t xHigherPriorityTaskWoken = pdFALSE;
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if(ctx->center && ctx->symbol != -1) {
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/*
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gpio_write(&debug_0, true);
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delay_us(symbol ? 10 : 30);
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gpio_write(&debug_0, false);
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*/
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ctx->int_buffer[ctx->symbol_cnt] = ctx->symbol;
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ctx->symbol_cnt++;
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}
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// check preamble
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if(ctx->symbol_cnt <= 9 && ctx->symbol == 0) {
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ctx->symbol_cnt = 0;
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ctx->symbol = -1;
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}
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// check stop bit
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if(ctx->symbol_cnt == 64 && ctx->symbol == 1) {
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ctx->symbol_cnt = 0;
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ctx->symbol = -1;
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}
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// TODO
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// write only 9..64 symbols directly to streambuffer
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if(ctx->symbol_cnt == 64) {
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if(xStreamBufferSendFromISR(
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ctx->stream_buffer, ctx->int_buffer, 64, &xHigherPriorityTaskWoken) == 64) {
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AppEvent event;
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event.type = EventTypeRx;
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osMessageQueuePut(ctx->event_queue, &event, 0, 0);
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}
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ctx->symbol_cnt = 0;
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}
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gpio_write(&debug_0, false);
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portYIELD_FROM_ISR(xHigherPriorityTaskWoken);
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}
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const uint8_t ROW_SIZE = 4;
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const uint8_t LINE_SIZE = 10;
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static bool even_check(uint8_t* buf) {
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uint8_t col_parity_sum[ROW_SIZE];
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for(uint8_t col = 0; col < ROW_SIZE; col++) {
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col_parity_sum[col] = 0;
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}
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// line parity
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for(uint8_t line = 0; line < LINE_SIZE; line++) {
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printf("%d: ", line);
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uint8_t parity_sum = 0;
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for(uint8_t col = 0; col < ROW_SIZE; col++) {
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parity_sum += buf[line * (ROW_SIZE + 1) + col];
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col_parity_sum[col] += buf[line * (ROW_SIZE + 1) + col];
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printf("%d ", buf[line * (ROW_SIZE + 1) + col]);
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}
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if((1 & parity_sum) != buf[line * (ROW_SIZE + 1) + ROW_SIZE]) {
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printf(
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"line parity fail at %d (%d : %d)\n",
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line,
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parity_sum,
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buf[line * (ROW_SIZE + 1) + ROW_SIZE]);
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return false;
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}
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printf("\r\n");
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}
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for(uint8_t col = 0; col < ROW_SIZE; col++) {
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if((1 & col_parity_sum[col]) != buf[LINE_SIZE * (ROW_SIZE + 1) + col]) {
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printf(
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"col parity fail at %d (%d : %d)\n",
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col,
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col_parity_sum[col],
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buf[LINE_SIZE * (ROW_SIZE + 1) + col]);
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return false;
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}
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}
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return true;
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}
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static void extract_data(uint8_t* buf, uint8_t* customer, uint32_t* em_data) {
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uint32_t data = 0;
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uint8_t offset = 0;
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printf("customer: ");
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for(uint8_t line = 0; line < 2; line++) {
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for(uint8_t col = 0; col < ROW_SIZE; col++) {
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uint32_t bit = buf[line * (ROW_SIZE + 1) + col];
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data |= bit << (7 - offset);
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printf("%ld ", bit);
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offset++;
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}
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}
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printf("\r\n");
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*customer = data;
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data = 0;
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offset = 0;
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printf("data: ");
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for(uint8_t line = 2; line < LINE_SIZE; line++) {
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for(uint8_t col = 0; col < ROW_SIZE; col++) {
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uint32_t bit = buf[line * (ROW_SIZE + 1) + col];
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data |= bit << (31 - offset);
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printf("%ld ", bit);
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offset++;
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}
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}
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printf("\r\n");
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*em_data = data;
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}
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int32_t lf_rfid_workaround(void* p) {
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osMessageQueueId_t event_queue = osMessageQueueNew(2, sizeof(AppEvent), NULL);
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// create pin
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GpioPin pull_pin = {.pin = RFID_PULL_Pin, .port = RFID_PULL_GPIO_Port};
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// TODO open record
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GpioPin* pull_pin_record = &pull_pin;
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gpio_init(pull_pin_record, GpioModeOutputPushPull);
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gpio_init(&debug_0, GpioModeOutputPushPull);
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gpio_init(&debug_1, GpioModeOutputPushPull);
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// pulldown iBtn pin to prevent interference from ibutton
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gpio_init((GpioPin*)&ibutton_gpio, GpioModeOutputOpenDrain);
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gpio_write((GpioPin*)&ibutton_gpio, false);
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// init ctx
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ComparatorCtx comp_ctx;
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// internal buffer
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uint8_t int_bufer[64];
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comp_ctx.stream_buffer = xStreamBufferCreate(64, 64);
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comp_ctx.int_buffer = int_bufer;
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comp_ctx.event_queue = event_queue;
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init_comp_ctx(&comp_ctx);
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if(comp_ctx.stream_buffer == NULL) {
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printf("cannot create stream buffer\r\n");
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return 255;
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}
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// start comp
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HAL_COMP_Start(&hcomp1);
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uint8_t raw_data[64];
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for(size_t i = 0; i < 64; i++) {
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raw_data[i] = 0;
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}
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State _state;
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_state.freq_khz = 125;
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_state.on = false;
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_state.customer_id = 00;
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_state.em_data = 4378151;
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_state.dirty = true;
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_state.dirty_freq = true;
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ValueMutex state_mutex;
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if(!init_mutex(&state_mutex, &_state, sizeof(State))) {
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printf("cannot create mutex\r\n");
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return 255;
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}
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ViewPort* view_port = view_port_alloc();
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view_port_draw_callback_set(view_port, render_callback, &state_mutex);
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view_port_input_callback_set(view_port, input_callback, event_queue);
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// Open GUI and register view_port
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Gui* gui = furi_record_open("gui");
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gui_add_view_port(gui, view_port, GuiLayerFullscreen);
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AppEvent event;
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while(1) {
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osStatus_t event_status = osMessageQueueGet(event_queue, &event, NULL, 1024 / 8);
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if(event.type == EventTypeRx && event_status == osOK) {
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size_t received = xStreamBufferReceive(comp_ctx.stream_buffer, raw_data, 64, 0);
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printf("received: %d\r\n", received);
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if(received == 64) {
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if(even_check(&raw_data[9])) {
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State* state = (State*)acquire_mutex_block(&state_mutex);
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extract_data(&raw_data[9], &state->customer_id, &state->em_data);
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printf("customer: %02d, data: %010lu\n", state->customer_id, state->em_data);
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release_mutex(&state_mutex, state);
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view_port_update(view_port);
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api_hal_light_set(LightGreen, 0xFF);
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osDelay(50);
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api_hal_light_set(LightGreen, 0x00);
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}
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}
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} else {
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State* state = (State*)acquire_mutex_block(&state_mutex);
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if(event_status == osOK) {
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if(event.type == EventTypeKey) {
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// press events
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if(event.value.input.type == InputTypePress &&
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event.value.input.key == InputKeyBack) {
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hal_pwmn_stop(&TIM_C, TIM_CHANNEL_1); // TODO: move to furiac_onexit
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api_interrupt_remove(
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comparator_trigger_callback, InterruptTypeComparatorTrigger);
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gpio_init(pull_pin_record, GpioModeInput);
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gpio_init((GpioPin*)&ibutton_gpio, GpioModeInput);
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// TODO remove all view_ports create by app
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view_port_enabled_set(view_port, false);
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return 255;
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}
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if(event.value.input.type == InputTypePress &&
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event.value.input.key == InputKeyUp) {
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state->dirty_freq = true;
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state->freq_khz += 10;
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}
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if(event.value.input.type == InputTypePress &&
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event.value.input.key == InputKeyDown) {
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state->dirty_freq = true;
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state->freq_khz -= 10;
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}
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if(event.value.input.type == InputTypePress &&
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event.value.input.key == InputKeyLeft) {
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}
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if(event.value.input.type == InputTypePress &&
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event.value.input.key == InputKeyRight) {
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}
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if(event.value.input.type == InputTypePress &&
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event.value.input.key == InputKeyOk) {
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state->dirty = true;
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state->on = !state->on;
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}
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}
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} else {
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// event timeout
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}
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if(state->dirty) {
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if(state->on) {
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gpio_write(pull_pin_record, false);
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init_comp_ctx(&comp_ctx);
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api_interrupt_add(
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comparator_trigger_callback, InterruptTypeComparatorTrigger, &comp_ctx);
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} else {
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prepare_data(state->em_data, state->customer_id, raw_data);
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api_interrupt_remove(
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comparator_trigger_callback, InterruptTypeComparatorTrigger);
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}
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state->dirty_freq = true; // config new PWM next
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state->dirty = false;
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}
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if(state->dirty_freq) {
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hal_pwmn_set(
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state->on ? 0.5 : 0.0, (float)(state->freq_khz * 1000), &LFRFID_TIM, LFRFID_CH);
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state->dirty_freq = false;
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}
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if(!state->on) {
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em4100_emulation(raw_data, pull_pin_record);
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}
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release_mutex(&state_mutex, state);
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view_port_update(view_port);
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}
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}
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return 0;
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}
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