mirror of
https://github.com/DarkFlippers/unleashed-firmware
synced 2024-12-18 00:33:09 +00:00
b405a22cd1
* api-hal-gpio: rework gpio on ll * one_wire_slave: rework gpio initialization * interrupts: add attribute weak to hal exti interrupts handlers * api-hal-gpio: add exti interrupt handlers * input: rework with api-hal-gpio interrupts * one_wire_slave: rework with api-hal-gpio interrupts * api-hal-gpio: fix incorrect exti line config * api-hal-gpio: add doxygen documentation * api-hal-gpio: add enable / disable interrupts * api-hal-gpio: add get_rfid_level * core: remove api-gpio * applications: rework gpio with api-hal-gpio * lib: rework gpio with api-hal-gpio * rfal: disable exti interrupt when rfal is inactive * rfal: add interrupt gpio reinitialization * api-hal-gpio: hide setting speed and pull mode LL implementation * stm32wbxx_it: remove unused EXTI handlers * api-hal-gpio: guard set, enable, disable and remove interrupt * Drop F4 target * Accessor: update gpio api usage Co-authored-by: Aleksandr Kutuzov <alleteam@gmail.com>
283 lines
No EOL
8.4 KiB
C++
283 lines
No EOL
8.4 KiB
C++
#pragma once
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#include <furi.h>
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#include "callback-connector.h"
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#include <atomic>
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enum class CyfralReaderCompError : uint8_t {
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NO_ERROR = 0,
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UNABLE_TO_DETECT = 1,
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RAW_DATA_SIZE_ERROR = 2,
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UNKNOWN_NIBBLE_VALUE = 3,
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NO_START_NIBBLE = 4,
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NOT_ENOUGH_DATA = 5,
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};
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extern COMP_HandleTypeDef hcomp1;
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typedef struct {
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bool value;
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uint32_t dwt_value;
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} CompEvent;
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class CyfralReaderComp {
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private:
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bool capture_data(bool* data, uint16_t capture_size);
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bool parse_data(bool* raw_data, uint16_t capture_size, uint8_t* data, uint8_t count);
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uint32_t search_array_in_array(
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const bool* haystack,
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const uint32_t haystack_size,
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const bool* needle,
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const uint32_t needle_size);
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// key is 9 nibbles
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static const uint16_t bits_in_nibble = 4;
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static const uint16_t key_length = 9;
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static const uint32_t capture_size = key_length * bits_in_nibble * 2;
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CyfralReaderCompError error;
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const GpioPin* pin_record;
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std::atomic<bool> ready_to_process;
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void comparator_trigger_callback(void* hcomp, void* comp_ctx);
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osMessageQueueId_t comp_event_queue;
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public:
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CyfralReaderComp(const GpioPin* emulate_pin);
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~CyfralReaderComp();
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void start(void);
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void stop(void);
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bool read(uint8_t* data, uint8_t count);
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};
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bool CyfralReaderComp::capture_data(bool* data, uint16_t capture_size) {
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uint32_t prev_timing = 0;
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uint16_t data_index = 0;
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CompEvent event_0, event_1;
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osStatus_t status;
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// read first event to get initial timing
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status = osMessageQueueGet(comp_event_queue, &event_0, NULL, 0);
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if(status != osOK) {
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return false;
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}
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prev_timing = event_0.dwt_value;
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// read second event until we get 0
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while(1) {
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status = osMessageQueueGet(comp_event_queue, &event_0, NULL, 0);
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if(status != osOK) {
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return false;
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}
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prev_timing = event_0.dwt_value;
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if(event_0.value == 0) break;
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}
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while(1) {
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// if event "zero" correct
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if(status == osOK && event_0.value == 0) {
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// get timing
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event_0.dwt_value -= prev_timing;
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prev_timing += event_0.dwt_value;
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// read next event
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status = osMessageQueueGet(comp_event_queue, &event_1, NULL, 0);
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// if event "one" correct
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if(status == osOK && event_1.value == 1) {
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// get timing
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event_1.dwt_value -= prev_timing;
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prev_timing += event_1.dwt_value;
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// calculate percentage of event "one" to full timing
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uint32_t full_timing = event_0.dwt_value + event_1.dwt_value;
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uint32_t percentage_1 = 1000000 / full_timing * event_1.dwt_value;
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// write captured data
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data[data_index] = percentage_1 > 500000 ? 0 : 1;
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data_index++;
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if(data_index >= capture_size) return true;
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status = osMessageQueueGet(comp_event_queue, &event_0, NULL, 0);
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} else {
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return false;
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}
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} else {
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return false;
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}
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}
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osMessageQueueReset(comp_event_queue);
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}
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uint32_t CyfralReaderComp::search_array_in_array(
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const bool* haystack,
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const uint32_t haystack_size,
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const bool* needle,
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const uint32_t needle_size) {
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uint32_t haystack_index = 0, needle_index = 0;
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while(haystack_index < haystack_size && needle_index < needle_size) {
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if(haystack[haystack_index] == needle[needle_index]) {
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haystack_index++;
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needle_index++;
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if(needle_index == needle_size) {
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return (haystack_index - needle_size);
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};
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} else {
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haystack_index = haystack_index - needle_index + 1;
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needle_index = 0;
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}
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}
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return haystack_index;
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}
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void CyfralReaderComp::comparator_trigger_callback(void* hcomp, void* comp_ctx) {
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CyfralReaderComp* _this = static_cast<CyfralReaderComp*>(comp_ctx);
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COMP_HandleTypeDef* _hcomp = static_cast<COMP_HandleTypeDef*>(hcomp);
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// check that hw is comparator 1
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if(_hcomp != &hcomp1) return;
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// if queue if not full
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if(_this->ready_to_process == false) {
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// send event to queue
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CompEvent event;
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// TOOD F4 and F5 differ
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event.value = (HAL_COMP_GetOutputLevel(_hcomp) == COMP_OUTPUT_LEVEL_LOW);
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event.dwt_value = DWT->CYCCNT;
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osStatus_t status = osMessageQueuePut(_this->comp_event_queue, &event, 0, 0);
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// queue is full, so we need to process data
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if(status != osOK) {
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_this->ready_to_process = true;
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};
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}
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}
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bool CyfralReaderComp::parse_data(
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bool* raw_data,
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uint16_t capture_size,
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uint8_t* data,
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uint8_t count) {
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const bool start_nibble[bits_in_nibble] = {1, 1, 1, 0};
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uint32_t start_position =
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search_array_in_array(raw_data, capture_size, start_nibble, bits_in_nibble);
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uint32_t end_position = 0;
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memset(data, 0, count);
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if(start_position < capture_size) {
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start_position = start_position + bits_in_nibble;
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end_position = start_position + count * 2 * bits_in_nibble;
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if(end_position >= capture_size) {
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error = CyfralReaderCompError::RAW_DATA_SIZE_ERROR;
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return false;
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}
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bool first_nibble = true;
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uint8_t data_position = 0;
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uint8_t nibble_value = 0;
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while(data_position < count) {
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nibble_value = !raw_data[start_position] << 3 | !raw_data[start_position + 1] << 2 |
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!raw_data[start_position + 2] << 1 | !raw_data[start_position + 3];
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switch(nibble_value) {
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case(0x7):
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case(0xB):
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case(0xD):
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case(0xE):
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break;
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default:
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error = CyfralReaderCompError::UNKNOWN_NIBBLE_VALUE;
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return false;
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break;
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}
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if(first_nibble) {
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data[data_position] |= nibble_value << 4;
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} else {
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data[data_position] |= nibble_value;
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}
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first_nibble = !first_nibble;
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if(first_nibble) {
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data_position++;
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}
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start_position = start_position + bits_in_nibble;
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}
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error = CyfralReaderCompError::NO_ERROR;
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return true;
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}
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error = CyfralReaderCompError::NO_START_NIBBLE;
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return false;
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}
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CyfralReaderComp::CyfralReaderComp(const GpioPin* gpio_pin) {
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pin_record = gpio_pin;
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}
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CyfralReaderComp::~CyfralReaderComp() {
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}
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void CyfralReaderComp::start(void) {
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// pulldown lf-rfid pins to prevent interference
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// TODO open record
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GpioPin rfid_pull_pin = {.port = RFID_PULL_GPIO_Port, .pin = RFID_PULL_Pin};
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hal_gpio_init((GpioPin*)&rfid_pull_pin, GpioModeOutputOpenDrain, GpioPullNo, GpioSpeedLow);
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hal_gpio_write((GpioPin*)&rfid_pull_pin, false);
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// TODO open record
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GpioPin rfid_out_pin = {.port = RFID_OUT_GPIO_Port, .pin = RFID_OUT_Pin};
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hal_gpio_init((GpioPin*)&rfid_out_pin, GpioModeOutputOpenDrain, GpioPullNo, GpioSpeedLow);
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hal_gpio_write((GpioPin*)&rfid_out_pin, false);
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// connect comparator callback
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void* comp_ctx = this;
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comp_event_queue = osMessageQueueNew(capture_size * 2 + 2, sizeof(CompEvent), NULL);
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ready_to_process = false;
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auto cmp_cb = cbc::obtain_connector(this, &CyfralReaderComp::comparator_trigger_callback);
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api_interrupt_add(cmp_cb, InterruptTypeComparatorTrigger, comp_ctx);
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// start comaparator
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HAL_COMP_Start(&hcomp1);
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}
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void CyfralReaderComp::stop(void) {
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// stop comaparator
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HAL_COMP_Stop(&hcomp1);
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// disconnect comparator callback
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auto cmp_cb = cbc::obtain_connector(this, &CyfralReaderComp::comparator_trigger_callback);
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api_interrupt_remove(cmp_cb, InterruptTypeComparatorTrigger);
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osMessageQueueDelete(comp_event_queue);
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}
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bool CyfralReaderComp::read(uint8_t* data, uint8_t count) {
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bool raw_data[capture_size];
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bool result = false;
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error = CyfralReaderCompError::NO_ERROR;
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if(ready_to_process == false) {
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error = CyfralReaderCompError::NOT_ENOUGH_DATA;
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} else {
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memset(raw_data, 0, sizeof(bool) * capture_size);
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if(capture_data(raw_data, capture_size)) {
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if(parse_data(raw_data, capture_size, data, count)) {
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result = true;
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}
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}
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ready_to_process = false;
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}
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return result;
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} |