#include "key-reader.h" #include "key-commands.h" #include #include extern COMP_HandleTypeDef hcomp1; KeyReader::Error KeyReader::read(iButtonKey* key) { uint8_t tmp_key_data[8] = {0, 0, 0, 0, 0, 0, 0, 0}; iButtonKeyType key_type; KeyReader::Error result = KeyReader::Error::EMPTY; if(read_key(&key_type, tmp_key_data, 8)) { switch(key_type) { case iButtonKeyType::KeyDallas: if(verify_key(key_type, tmp_key_data, 8)) { if(maxim_crc8(tmp_key_data, 8) == 0) { if(tmp_key_data[0] == 0x01) { result = KeyReader::Error::OK; } else { result = KeyReader::Error::NOT_ARE_KEY; } } else { result = KeyReader::Error::CRC_ERROR; } } break; case iButtonKeyType::KeyCyfral: result = KeyReader::Error::OK; break; case iButtonKeyType::KeyMetakom: result = KeyReader::Error::OK; break; } if(result != KeyReader::Error::EMPTY) { key->set_type(key_type); key->set_data(tmp_key_data, 8); } } switch_mode_if_needed(); return result; } KeyReader::KeyReader(OneWireMaster* _onewire_master) { onewire_master = _onewire_master; read_mode_switch_time = 0; read_mode = ReadMode::DALLAS; } KeyReader::~KeyReader() { stop(); } bool KeyReader::read_key(iButtonKeyType* key_type, uint8_t* data, uint8_t data_size) { bool readed = false; switch(read_mode) { case ReadMode::DALLAS: if(onewire_master->search(data)) { onewire_master->reset_search(); readed = true; *key_type = iButtonKeyType::KeyDallas; } else { onewire_master->reset_search(); } break; case ReadMode::CYFRAL_METAKOM: if(cyfral_decoder.read(data, 2)) { readed = true; *key_type = iButtonKeyType::KeyCyfral; } else if(metakom_decoder.read(data, 4)) { readed = true; *key_type = iButtonKeyType::KeyMetakom; } break; } return readed; } bool KeyReader::verify_key(iButtonKeyType key_type, const uint8_t* const data, uint8_t data_size) { bool result = true; switch(key_type) { case iButtonKeyType::KeyDallas: switch_to(ReadMode::DALLAS); if(onewire_master->reset()) { onewire_master->write(DS1990::CMD_READ_ROM); for(uint8_t i = 0; i < data_size; i++) { if(onewire_master->read() != data[i]) { result = false; } } } else { result = false; break; } break; default: result = false; break; } return result; } void KeyReader::start_comaparator(void) { // pulldown lf-rfid pins to prevent interference // TODO open record GpioPin rfid_pull_pin = {.port = RFID_PULL_GPIO_Port, .pin = RFID_PULL_Pin}; gpio_init(&rfid_pull_pin, GpioModeOutputOpenDrain); gpio_write(&rfid_pull_pin, false); // TODO open record GpioPin rfid_out_pin = {.port = RFID_OUT_GPIO_Port, .pin = RFID_OUT_Pin}; gpio_init(&rfid_out_pin, GpioModeOutputOpenDrain); gpio_write(&rfid_out_pin, false); comparator_callback_pointer = cbc::obtain_connector(this, &KeyReader::comparator_trigger_callback); api_interrupt_add(comparator_callback_pointer, InterruptTypeComparatorTrigger, this); last_dwt_value = DWT->CYCCNT; HAL_COMP_Start(&hcomp1); } void KeyReader::stop_comaparator(void) { HAL_COMP_Stop(&hcomp1); api_interrupt_remove(comparator_callback_pointer, InterruptTypeComparatorTrigger); } void KeyReader::comparator_trigger_callback(void* hcomp, void* comp_ctx) { KeyReader* _this = static_cast(comp_ctx); if(hcomp == &hcomp1) { _this->cyfral_decoder.process_front(get_rfid_in_level(), DWT->CYCCNT - last_dwt_value); _this->metakom_decoder.process_front(get_rfid_in_level(), DWT->CYCCNT - last_dwt_value); last_dwt_value = DWT->CYCCNT; } } void KeyReader::switch_to(ReadMode mode) { switch(mode) { case ReadMode::DALLAS: onewire_master->start(); stop_comaparator(); break; case ReadMode::CYFRAL_METAKOM: onewire_master->stop(); start_comaparator(); break; } read_mode = mode; } void KeyReader::switch_mode_if_needed() { if(osKernelGetTickCount() - read_mode_switch_time > (osKernelGetTickFreq() / 5)) { read_mode_switch_time = osKernelGetTickCount(); switch(read_mode) { case ReadMode::DALLAS: switch_to(ReadMode::CYFRAL_METAKOM); break; case ReadMode::CYFRAL_METAKOM: switch_to(ReadMode::DALLAS); break; } } } void KeyReader::start() { api_hal_power_enable_otg(); switch_to(ReadMode::CYFRAL_METAKOM); } void KeyReader::stop() { api_hal_power_disable_otg(); onewire_master->stop(); stop_comaparator(); }