diff --git a/CODEOWNERS b/CODEOWNERS index 1722f482ac..cc322862e5 100644 --- a/CODEOWNERS +++ b/CODEOWNERS @@ -44,6 +44,7 @@ esphome/components/output/* @esphome/core esphome/components/pid/* @OttoWinter esphome/components/pn532/* @OttoWinter esphome/components/power_supply/* @esphome/core +esphome/components/rc522_spi/* @glmnet esphome/components/restart/* @esphome/core esphome/components/rf_bridge/* @jesserockz esphome/components/rtttl/* @glmnet diff --git a/esphome/components/rc522_spi/__init__.py b/esphome/components/rc522_spi/__init__.py new file mode 100644 index 0000000000..043d083c4c --- /dev/null +++ b/esphome/components/rc522_spi/__init__.py @@ -0,0 +1,39 @@ +import esphome.codegen as cg +import esphome.config_validation as cv +from esphome import automation, pins +from esphome.components import spi +from esphome.const import CONF_ID, CONF_ON_TAG, CONF_TRIGGER_ID, CONF_RESET_PIN, CONF_CS_PIN + +CODEOWNERS = ['@glmnet'] +DEPENDENCIES = ['spi'] +AUTO_LOAD = ['binary_sensor'] +MULTI_CONF = True + + +rc522_spi_ns = cg.esphome_ns.namespace('rc522_spi') +RC522 = rc522_spi_ns.class_('RC522', cg.PollingComponent, spi.SPIDevice) +RC522Trigger = rc522_spi_ns.class_('RC522Trigger', automation.Trigger.template(cg.std_string)) + +CONFIG_SCHEMA = cv.Schema({ + cv.GenerateID(): cv.declare_id(RC522), + cv.Optional(CONF_RESET_PIN): pins.gpio_output_pin_schema, + cv.Required(CONF_CS_PIN): pins.gpio_output_pin_schema, + cv.Optional(CONF_ON_TAG): automation.validate_automation({ + cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(RC522Trigger), + }), +}).extend(cv.polling_component_schema('1s')).extend(spi.spi_device_schema()) + + +def to_code(config): + var = cg.new_Pvariable(config[CONF_ID]) + yield cg.register_component(var, config) + yield spi.register_spi_device(var, config) + + if CONF_RESET_PIN in config: + reset = yield cg.gpio_pin_expression(config[CONF_RESET_PIN]) + cg.add(var.set_reset_pin(reset)) + + for conf in config.get(CONF_ON_TAG, []): + trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID]) + cg.add(var.register_trigger(trigger)) + yield automation.build_automation(trigger, [(cg.std_string, 'x')], conf) diff --git a/esphome/components/rc522_spi/binary_sensor.py b/esphome/components/rc522_spi/binary_sensor.py new file mode 100644 index 0000000000..d58d62c797 --- /dev/null +++ b/esphome/components/rc522_spi/binary_sensor.py @@ -0,0 +1,44 @@ +import esphome.codegen as cg +import esphome.config_validation as cv +from esphome.components import binary_sensor +from esphome.const import CONF_UID, CONF_ID +from esphome.core import HexInt +from . import rc522_spi_ns, RC522 + +DEPENDENCIES = ['rc522_spi'] + +CONF_RC522_ID = 'rc522_id' + + +def validate_uid(value): + value = cv.string_strict(value) + for x in value.split('-'): + if len(x) != 2: + raise cv.Invalid("Each part (separated by '-') of the UID must be two characters " + "long.") + try: + x = int(x, 16) + except ValueError as err: + raise cv.Invalid("Valid characters for parts of a UID are 0123456789ABCDEF.") from err + if x < 0 or x > 255: + raise cv.Invalid("Valid values for UID parts (separated by '-') are 00 to FF") + return value + + +RC522BinarySensor = rc522_spi_ns.class_('RC522BinarySensor', binary_sensor.BinarySensor) + +CONFIG_SCHEMA = binary_sensor.BINARY_SENSOR_SCHEMA.extend({ + cv.GenerateID(): cv.declare_id(RC522BinarySensor), + cv.GenerateID(CONF_RC522_ID): cv.use_id(RC522), + cv.Required(CONF_UID): validate_uid, +}) + + +def to_code(config): + var = cg.new_Pvariable(config[CONF_ID]) + yield binary_sensor.register_binary_sensor(var, config) + + hub = yield cg.get_variable(config[CONF_RC522_ID]) + cg.add(hub.register_tag(var)) + addr = [HexInt(int(x, 16)) for x in config[CONF_UID].split('-')] + cg.add(var.set_uid(addr)) diff --git a/esphome/components/rc522_spi/rc522_spi.cpp b/esphome/components/rc522_spi/rc522_spi.cpp new file mode 100644 index 0000000000..b332e50c53 --- /dev/null +++ b/esphome/components/rc522_spi/rc522_spi.cpp @@ -0,0 +1,857 @@ +#include "rc522_spi.h" +#include "esphome/core/log.h" + +// Based on: +// - https://github.com/miguelbalboa/rfid + +namespace esphome { +namespace rc522_spi { + +static const char *TAG = "rc522_spi"; + +static const uint8_t RESET_COUNT = 5; + +void format_uid(char *buf, const uint8_t *uid, uint8_t uid_length) { + int offset = 0; + for (uint8_t i = 0; i < uid_length; i++) { + const char *format = "%02X"; + if (i + 1 < uid_length) + format = "%02X-"; + offset += sprintf(buf + offset, format, uid[i]); + } +} + +void RC522::setup() { + spi_setup(); + initialize_pending_ = true; + // Pull device out of power down / reset state. + + // First set the resetPowerDownPin as digital input, to check the MFRC522 power down mode. + if (reset_pin_ != nullptr) { + reset_pin_->pin_mode(INPUT); + + if (reset_pin_->digital_read() == LOW) { // The MFRC522 chip is in power down mode. + ESP_LOGV(TAG, "Power down mode detected. Hard resetting..."); + reset_pin_->pin_mode(OUTPUT); // Now set the resetPowerDownPin as digital output. + reset_pin_->digital_write(LOW); // Make sure we have a clean LOW state. + delayMicroseconds(2); // 8.8.1 Reset timing requirements says about 100ns. Let us be generous: 2μsl + reset_pin_->digital_write(HIGH); // Exit power down mode. This triggers a hard reset. + // Section 8.8.2 in the datasheet says the oscillator start-up time is the start up time of the crystal + 37,74μs. + // Let us be generous: 50ms. + reset_timeout_ = millis(); + return; + } + } + + // Setup a soft reset + reset_count_ = RESET_COUNT; + reset_timeout_ = millis(); +} + +void RC522::initialize_() { + // Per originall code, wait 50 ms + if (millis() - reset_timeout_ < 50) + return; + + // Reset baud rates + ESP_LOGV(TAG, "Initialize"); + + pcd_write_register_(TX_MODE_REG, 0x00); + pcd_write_register_(RX_MODE_REG, 0x00); + // Reset ModWidthReg + pcd_write_register_(MOD_WIDTH_REG, 0x26); + + // When communicating with a PICC we need a timeout if something goes wrong. + // f_timer = 13.56 MHz / (2*TPreScaler+1) where TPreScaler = [TPrescaler_Hi:TPrescaler_Lo]. + // TPrescaler_Hi are the four low bits in TModeReg. TPrescaler_Lo is TPrescalerReg. + pcd_write_register_(T_MODE_REG, 0x80); // TAuto=1; timer starts automatically at the end of the transmission in all + // communication modes at all speeds + + // TPreScaler = TModeReg[3..0]:TPrescalerReg, ie 0x0A9 = 169 => f_timer=40kHz, ie a timer period of 25μs. + pcd_write_register_(T_PRESCALER_REG, 0xA9); + pcd_write_register_(T_RELOAD_REG_H, 0x03); // Reload timer with 0x3E8 = 1000, ie 25ms before timeout. + pcd_write_register_(T_RELOAD_REG_L, 0xE8); + + // Default 0x00. Force a 100 % ASK modulation independent of the ModGsPReg register setting + pcd_write_register_(TX_ASK_REG, 0x40); + pcd_write_register_(MODE_REG, 0x3D); // Default 0x3F. Set the preset value for the CRC coprocessor for the CalcCRC + // command to 0x6363 (ISO 14443-3 part 6.2.4) + pcd_antenna_on_(); // Enable the antenna driver pins TX1 and TX2 (they were disabled by the reset) + + initialize_pending_ = false; +} + +void RC522::dump_config() { + ESP_LOGCONFIG(TAG, "RC522:"); + switch (this->error_code_) { + case NONE: + break; + case RESET_FAILED: + ESP_LOGE(TAG, "Reset command failed!"); + break; + } + + LOG_PIN(" CS Pin: ", this->cs_); + LOG_PIN(" RESET Pin: ", this->reset_pin_); + + LOG_UPDATE_INTERVAL(this); + + for (auto *child : this->binary_sensors_) { + LOG_BINARY_SENSOR(" ", "Tag", child); + } +} + +void RC522::loop() { + // First check reset is needed + if (reset_count_ > 0) { + pcd_reset_(); + return; + } + if (initialize_pending_) { + initialize_(); + return; + } + + if (millis() - update_wait_ < this->update_interval_) + return; + + auto status = picc_is_new_card_present_(); + + if (status == STATUS_ERROR) // No card + { + ESP_LOGE(TAG, "Error"); + // mark_failed(); + return; + } + + if (status != STATUS_OK) // We can receive STATUS_TIMEOUT when no card, or unexpected status. + return; + + // Try process card + if (!picc_read_card_serial_()) { + ESP_LOGW(TAG, "Requesting tag read failed!"); + return; + }; + + if (uid_.size < 4) { + return; + ESP_LOGW(TAG, "Read serial size: %d", uid_.size); + } + + update_wait_ = millis(); + + bool report = true; + // 1. Go through all triggers + for (auto *trigger : this->triggers_) + trigger->process(uid_.uiduint8_t, uid_.size); + + // 2. Find a binary sensor + for (auto *tag : this->binary_sensors_) { + if (tag->process(uid_.uiduint8_t, uid_.size)) { + // 2.1 if found, do not dump + report = false; + } + } + + if (report) { + char buf[32]; + format_uid(buf, uid_.uiduint8_t, uid_.size); + ESP_LOGD(TAG, "Found new tag '%s'", buf); + } +} + +void RC522::update() { + for (auto *obj : this->binary_sensors_) + obj->on_scan_end(); +} + +/** + * Performs a soft reset on the MFRC522 chip and waits for it to be ready again. + */ +void RC522::pcd_reset_() { + // The datasheet does not mention how long the SoftRest command takes to complete. + // But the MFRC522 might have been in soft power-down mode (triggered by bit 4 of CommandReg) + // Section 8.8.2 in the datasheet says the oscillator start-up time is the start up time of the crystal + 37,74μs. Let + // us be generous: 50ms. + + if (millis() - reset_timeout_ < 50) + return; + + if (reset_count_ == RESET_COUNT) { + ESP_LOGV(TAG, "Soft reset..."); + // Issue the SoftReset command. + pcd_write_register_(COMMAND_REG, PCD_SOFT_RESET); + } + + // Expect the PowerDown bit in CommandReg to be cleared (max 3x50ms) + if ((pcd_read_register_(COMMAND_REG) & (1 << 4)) == 0) { + reset_count_ = 0; + ESP_LOGI(TAG, "Device online."); + // Wait for initialize + reset_timeout_ = millis(); + return; + } + + if (--reset_count_ == 0) { + ESP_LOGE(TAG, "Unable to reset RC522."); + mark_failed(); + } +} + +/** + * Turns the antenna on by enabling pins TX1 and TX2. + * After a reset these pins are disabled. + */ +void RC522::pcd_antenna_on_() { + uint8_t value = pcd_read_register_(TX_CONTROL_REG); + if ((value & 0x03) != 0x03) { + pcd_write_register_(TX_CONTROL_REG, value | 0x03); + } +} + +/** + * Reads a uint8_t from the specified register in the MFRC522 chip. + * The interface is described in the datasheet section 8.1.2. + */ +uint8_t RC522::pcd_read_register_(PcdRegister reg ///< The register to read from. One of the PCD_Register enums. +) { + uint8_t value; + enable(); + transfer_byte(0x80 | reg); + value = read_byte(); + disable(); + ESP_LOGVV(TAG, "read_register_(%x) -> %x", reg, value); + return value; +} + +/** + * Reads a number of uint8_ts from the specified register in the MFRC522 chip. + * The interface is described in the datasheet section 8.1.2. + */ +void RC522::pcd_read_register_(PcdRegister reg, ///< The register to read from. One of the PCD_Register enums. + uint8_t count, ///< The number of uint8_ts to read + uint8_t *values, ///< uint8_t array to store the values in. + uint8_t rx_align ///< Only bit positions rxAlign..7 in values[0] are updated. +) { + std::string buf; + buf = "Rx"; + char cstrb[20]; + if (count == 0) { + return; + } + + // Serial.print(F("Reading ")); Serial.print(count); Serial.println(F(" uint8_ts from register.")); + uint8_t address = 0x80 | reg; // MSB == 1 is for reading. LSB is not used in address. Datasheet section 8.1.2.3. + uint8_t index = 0; // Index in values array. + enable(); + count--; // One read is performed outside of the loop + + write_byte(address); // Tell MFRC522 which address we want to read + if (rx_align) { // Only update bit positions rxAlign..7 in values[0] + // Create bit mask for bit positions rxAlign..7 + uint8_t mask = 0xFF << rx_align; + // Read value and tell that we want to read the same address again. + uint8_t value = transfer_byte(address); + // Apply mask to both current value of values[0] and the new data in value. + values[0] = (values[0] & ~mask) | (value & mask); + index++; + + sprintf(cstrb, " %x", values[0]); + buf.append(cstrb); + } + while (index < count) { + values[index] = transfer_byte(address); // Read value and tell that we want to read the same address again. + + sprintf(cstrb, " %x", values[index]); + buf.append(cstrb); + + index++; + } + values[index] = transfer_byte(0); // Read the final uint8_t. Send 0 to stop reading. + + buf = buf + " "; + sprintf(cstrb, "%x", values[index]); + buf.append(cstrb); + + ESP_LOGVV(TAG, "read_register_array_(%x, %d, , %d) -> %s", reg, count, rx_align, buf.c_str()); + + disable(); +} + +void RC522::pcd_write_register_(PcdRegister reg, ///< The register to write to. One of the PCD_Register enums. + uint8_t value ///< The value to write. +) { + enable(); + // MSB == 0 is for writing. LSB is not used in address. Datasheet section 8.1.2.3. + transfer_byte(reg); + transfer_byte(value); + disable(); +} + +/** + * Writes a number of uint8_ts to the specified register in the MFRC522 chip. + * The interface is described in the datasheet section 8.1.2. + */ +void RC522::pcd_write_register_(PcdRegister reg, ///< The register to write to. One of the PCD_Register enums. + uint8_t count, ///< The number of uint8_ts to write to the register + uint8_t *values ///< The values to write. uint8_t array. +) { + std::string buf; + buf = "Tx"; + + enable(); + transfer_byte(reg); + char cstrb[20]; + + for (uint8_t index = 0; index < count; index++) { + transfer_byte(values[index]); + + sprintf(cstrb, " %x", values[index]); + buf.append(cstrb); + } + disable(); + ESP_LOGVV(TAG, "write_register_(%x, %d) -> %s", reg, count, buf.c_str()); +} + +/** + * Transmits a REQuest command, Type A. Invites PICCs in state IDLE to go to READY and prepare for anticollision or + * selection. 7 bit frame. Beware: When two PICCs are in the field at the same time I often get STATUS_TIMEOUT - + * probably due do bad antenna design. + * + * @return STATUS_OK on success, STATUS_??? otherwise. + */ +RC522::StatusCode RC522::picc_request_a_( + uint8_t *buffer_atqa, ///< The buffer to store the ATQA (Answer to request) in + uint8_t *buffer_size ///< Buffer size, at least two uint8_ts. Also number of uint8_ts returned if STATUS_OK. +) { + return picc_reqa_or_wupa_(PICC_CMD_REQA, buffer_atqa, buffer_size); +} + +/** + * Transmits REQA or WUPA commands. + * Beware: When two PICCs are in the field at the same time I often get STATUS_TIMEOUT - probably due do bad antenna + * design. + * + * @return STATUS_OK on success, STATUS_??? otherwise. + */ +RC522::StatusCode RC522::picc_reqa_or_wupa_( + uint8_t command, ///< The command to send - PICC_CMD_REQA or PICC_CMD_WUPA + uint8_t *buffer_atqa, ///< The buffer to store the ATQA (Answer to request) in + uint8_t *buffer_size ///< Buffer size, at least two uint8_ts. Also number of uint8_ts returned if STATUS_OK. +) { + uint8_t valid_bits; + RC522::StatusCode status; + + if (buffer_atqa == nullptr || *buffer_size < 2) { // The ATQA response is 2 uint8_ts long. + return STATUS_NO_ROOM; + } + pcd_clear_register_bit_mask_(COLL_REG, 0x80); // ValuesAfterColl=1 => Bits received after collision are cleared. + valid_bits = 7; // For REQA and WUPA we need the short frame format - transmit only 7 bits of the last (and only) + // uint8_t. TxLastBits = BitFramingReg[2..0] + status = pcd_transceive_data_(&command, 1, buffer_atqa, buffer_size, &valid_bits); + if (status != STATUS_OK) + return status; + if (*buffer_size != 2 || valid_bits != 0) { // ATQA must be exactly 16 bits. + ESP_LOGVV(TAG, "picc_reqa_or_wupa_() -> STATUS_ERROR"); + return STATUS_ERROR; + } + + return STATUS_OK; +} + +/** + * Sets the bits given in mask in register reg. + */ +void RC522::pcd_set_register_bit_mask_(PcdRegister reg, ///< The register to update. One of the PCD_Register enums. + uint8_t mask ///< The bits to set. +) { + uint8_t tmp = pcd_read_register_(reg); + pcd_write_register_(reg, tmp | mask); // set bit mask +} + +/** + * Clears the bits given in mask from register reg. + */ +void RC522::pcd_clear_register_bit_mask_(PcdRegister reg, ///< The register to update. One of the PCD_Register enums. + uint8_t mask ///< The bits to clear. +) { + uint8_t tmp = pcd_read_register_(reg); + pcd_write_register_(reg, tmp & (~mask)); // clear bit mask +} + +/** + * Executes the Transceive command. + * CRC validation can only be done if backData and backLen are specified. + * + * @return STATUS_OK on success, STATUS_??? otherwise. + */ +RC522::StatusCode RC522::pcd_transceive_data_( + uint8_t *send_data, ///< Pointer to the data to transfer to the FIFO. + uint8_t send_len, ///< Number of uint8_ts to transfer to the FIFO. + uint8_t *back_data, ///< nullptr or pointer to buffer if data should be read back after executing the command. + uint8_t *back_len, ///< In: Max number of uint8_ts to write to *backData. Out: The number of uint8_ts returned. + uint8_t + *valid_bits, ///< In/Out: The number of valid bits in the last uint8_t. 0 for 8 valid bits. Default nullptr. + uint8_t rx_align, ///< In: Defines the bit position in backData[0] for the first bit received. Default 0. + bool check_crc ///< In: True => The last two uint8_ts of the response is assumed to be a CRC_A that must be + ///< validated. +) { + uint8_t wait_i_rq = 0x30; // RxIRq and IdleIRq + auto ret = pcd_communicate_with_picc_(PCD_TRANSCEIVE, wait_i_rq, send_data, send_len, back_data, back_len, valid_bits, + rx_align, check_crc); + + if (ret == STATUS_OK && *back_len == 5) + ESP_LOGVV(TAG, "pcd_transceive_data_(..., %d, ) -> %d [%x, %x, %x, %x, %x]", send_len, ret, back_data[0], + back_data[1], back_data[2], back_data[3], back_data[4]); + else + ESP_LOGVV(TAG, "pcd_transceive_data_(..., %d, ... ) -> %d", send_len, ret); + return ret; +} + +/** + * Transfers data to the MFRC522 FIFO, executes a command, waits for completion and transfers data back from the FIFO. + * CRC validation can only be done if backData and backLen are specified. + * + * @return STATUS_OK on success, STATUS_??? otherwise. + */ +RC522::StatusCode RC522::pcd_communicate_with_picc_( + uint8_t command, ///< The command to execute. One of the PCD_Command enums. + uint8_t wait_i_rq, ///< The bits in the ComIrqReg register that signals successful completion of the command. + uint8_t *send_data, ///< Pointer to the data to transfer to the FIFO. + uint8_t send_len, ///< Number of uint8_ts to transfer to the FIFO. + uint8_t *back_data, ///< nullptr or pointer to buffer if data should be read back after executing the command. + uint8_t *back_len, ///< In: Max number of uint8_ts to write to *backData. Out: The number of uint8_ts returned. + uint8_t *valid_bits, ///< In/Out: The number of valid bits in the last uint8_t. 0 for 8 valid bits. + uint8_t rx_align, ///< In: Defines the bit position in backData[0] for the first bit received. Default 0. + bool check_crc ///< In: True => The last two uint8_ts of the response is assumed to be a CRC_A that must be + ///< validated. +) { + ESP_LOGVV(TAG, "pcd_communicate_with_picc_(%d, %d,... %d)", command, wait_i_rq, check_crc); + + // Prepare values for BitFramingReg + uint8_t tx_last_bits = valid_bits ? *valid_bits : 0; + uint8_t bit_framing = + (rx_align << 4) + tx_last_bits; // RxAlign = BitFramingReg[6..4]. TxLastBits = BitFramingReg[2..0] + + pcd_write_register_(COMMAND_REG, PCD_IDLE); // Stop any active command. + pcd_write_register_(COM_IRQ_REG, 0x7F); // Clear all seven interrupt request bits + pcd_write_register_(FIFO_LEVEL_REG, 0x80); // FlushBuffer = 1, FIFO initialization + pcd_write_register_(FIFO_DATA_REG, send_len, send_data); // Write sendData to the FIFO + pcd_write_register_(BIT_FRAMING_REG, bit_framing); // Bit adjustments + pcd_write_register_(COMMAND_REG, command); // Execute the command + if (command == PCD_TRANSCEIVE) { + pcd_set_register_bit_mask_(BIT_FRAMING_REG, 0x80); // StartSend=1, transmission of data starts + } + + // Wait for the command to complete. + // In PCD_Init() we set the TAuto flag in TModeReg. This means the timer automatically starts when the PCD stops + // transmitting. Each iteration of the do-while-loop takes 17.86μs. + // TODO check/modify for other architectures than Arduino Uno 16bit + uint16_t i; + for (i = 2000; i > 0; i--) { + uint8_t n = pcd_read_register_( + COM_IRQ_REG); // ComIrqReg[7..0] bits are: Set1 TxIRq RxIRq IdleIRq HiAlertIRq LoAlertIRq ErrIRq TimerIRq + if (n & wait_i_rq) { // One of the interrupts that signal success has been set. + break; + } + if (n & 0x01) { // Timer interrupt - nothing received in 25ms + return STATUS_TIMEOUT; + } + } + // 35.7ms and nothing happend. Communication with the MFRC522 might be down. + if (i == 0) { + return STATUS_TIMEOUT; + } + + // Stop now if any errors except collisions were detected. + uint8_t error_reg_value = pcd_read_register_( + ERROR_REG); // ErrorReg[7..0] bits are: WrErr TempErr reserved BufferOvfl CollErr CRCErr ParityErr ProtocolErr + if (error_reg_value & 0x13) { // BufferOvfl ParityErr ProtocolErr + return STATUS_ERROR; + } + + uint8_t valid_bits_local = 0; + + // If the caller wants data back, get it from the MFRC522. + if (back_data && back_len) { + uint8_t n = pcd_read_register_(FIFO_LEVEL_REG); // Number of uint8_ts in the FIFO + if (n > *back_len) { + return STATUS_NO_ROOM; + } + *back_len = n; // Number of uint8_ts returned + pcd_read_register_(FIFO_DATA_REG, n, back_data, rx_align); // Get received data from FIFO + valid_bits_local = + pcd_read_register_(CONTROL_REG) & 0x07; // RxLastBits[2:0] indicates the number of valid bits in the last + // received uint8_t. If this value is 000b, the whole uint8_t is valid. + if (valid_bits) { + *valid_bits = valid_bits_local; + } + } + + // Tell about collisions + if (error_reg_value & 0x08) { // CollErr + return STATUS_COLLISION; + } + + // Perform CRC_A validation if requested. + if (back_data && back_len && check_crc) { + // In this case a MIFARE Classic NAK is not OK. + if (*back_len == 1 && valid_bits_local == 4) { + return STATUS_MIFARE_NACK; + } + // We need at least the CRC_A value and all 8 bits of the last uint8_t must be received. + if (*back_len < 2 || valid_bits_local != 0) { + return STATUS_CRC_WRONG; + } + // Verify CRC_A - do our own calculation and store the control in controlBuffer. + uint8_t control_buffer[2]; + RC522::StatusCode status = pcd_calculate_crc_(&back_data[0], *back_len - 2, &control_buffer[0]); + if (status != STATUS_OK) { + return status; + } + if ((back_data[*back_len - 2] != control_buffer[0]) || (back_data[*back_len - 1] != control_buffer[1])) { + return STATUS_CRC_WRONG; + } + } + + return STATUS_OK; +} + +/** + * Use the CRC coprocessor in the MFRC522 to calculate a CRC_A. + * + * @return STATUS_OK on success, STATUS_??? otherwise. + */ + +RC522::StatusCode RC522::pcd_calculate_crc_( + uint8_t *data, ///< In: Pointer to the data to transfer to the FIFO for CRC calculation. + uint8_t length, ///< In: The number of uint8_ts to transfer. + uint8_t *result ///< Out: Pointer to result buffer. Result is written to result[0..1], low uint8_t first. +) { + ESP_LOGVV(TAG, "pcd_calculate_crc_(..., %d, ...)", length); + pcd_write_register_(COMMAND_REG, PCD_IDLE); // Stop any active command. + pcd_write_register_(DIV_IRQ_REG, 0x04); // Clear the CRCIRq interrupt request bit + pcd_write_register_(FIFO_LEVEL_REG, 0x80); // FlushBuffer = 1, FIFO initialization + pcd_write_register_(FIFO_DATA_REG, length, data); // Write data to the FIFO + pcd_write_register_(COMMAND_REG, PCD_CALC_CRC); // Start the calculation + + // Wait for the CRC calculation to complete. Each iteration of the while-loop takes 17.73μs. + // TODO check/modify for other architectures than Arduino Uno 16bit + + // Wait for the CRC calculation to complete. Each iteration of the while-loop takes 17.73us. + for (uint16_t i = 5000; i > 0; i--) { + // DivIrqReg[7..0] bits are: Set2 reserved reserved MfinActIRq reserved CRCIRq reserved reserved + uint8_t n = pcd_read_register_(DIV_IRQ_REG); + if (n & 0x04) { // CRCIRq bit set - calculation done + pcd_write_register_(COMMAND_REG, PCD_IDLE); // Stop calculating CRC for new content in the FIFO. + // Transfer the result from the registers to the result buffer + result[0] = pcd_read_register_(CRC_RESULT_REG_L); + result[1] = pcd_read_register_(CRC_RESULT_REG_H); + + ESP_LOGVV(TAG, "pcd_calculate_crc_() STATUS_OK"); + return STATUS_OK; + } + } + ESP_LOGVV(TAG, "pcd_calculate_crc_() TIMEOUT"); + // 89ms passed and nothing happend. Communication with the MFRC522 might be down. + return STATUS_TIMEOUT; +} +/** + * Returns STATUS_OK if a PICC responds to PICC_CMD_REQA. + * Only "new" cards in state IDLE are invited. Sleeping cards in state HALT are ignored. + * + * @return STATUS_OK on success, STATUS_??? otherwise. + */ + +RC522::StatusCode RC522::picc_is_new_card_present_() { + uint8_t buffer_atqa[2]; + uint8_t buffer_size = sizeof(buffer_atqa); + + // Reset baud rates + pcd_write_register_(TX_MODE_REG, 0x00); + pcd_write_register_(RX_MODE_REG, 0x00); + // Reset ModWidthReg + pcd_write_register_(MOD_WIDTH_REG, 0x26); + + auto result = picc_request_a_(buffer_atqa, &buffer_size); + + ESP_LOGV(TAG, "picc_is_new_card_present_() -> %d", result); + return result; +} + +/** + * Simple wrapper around PICC_Select. + * Returns true if a UID could be read. + * Remember to call PICC_IsNewCardPresent(), PICC_RequestA() or PICC_WakeupA() first. + * The read UID is available in the class variable uid. + * + * @return bool + */ +bool RC522::picc_read_card_serial_() { + RC522::StatusCode result = picc_select_(&this->uid_); + ESP_LOGVV(TAG, "picc_select_(...) -> %d", result); + return (result == STATUS_OK); +} + +/** + * Transmits SELECT/ANTICOLLISION commands to select a single PICC. + * Before calling this function the PICCs must be placed in the READY(*) state by calling PICC_RequestA() or + * PICC_WakeupA(). On success: + * - The chosen PICC is in state ACTIVE(*) and all other PICCs have returned to state IDLE/HALT. (Figure 7 of the + * ISO/IEC 14443-3 draft.) + * - The UID size and value of the chosen PICC is returned in *uid along with the SAK. + * + * A PICC UID consists of 4, 7 or 10 uint8_ts. + * Only 4 uint8_ts can be specified in a SELECT command, so for the longer UIDs two or three iterations are used: + * UID size Number of UID uint8_ts Cascade levels Example of PICC + * ======== =================== ============== =============== + * single 4 1 MIFARE Classic + * double 7 2 MIFARE Ultralight + * triple 10 3 Not currently in use? + * + * @return STATUS_OK on success, STATUS_??? otherwise. + */ +RC522::StatusCode RC522::picc_select_( + Uid *uid, ///< Pointer to Uid struct. Normally output, but can also be used to supply a known UID. + uint8_t valid_bits ///< The number of known UID bits supplied in *uid. Normally 0. If set you must also supply + ///< uid->size. +) { + bool uid_complete; + bool select_done; + bool use_cascade_tag; + uint8_t cascade_level = 1; + RC522::StatusCode result; + uint8_t count; + uint8_t check_bit; + uint8_t index; + uint8_t uid_index; // The first index in uid->uiduint8_t[] that is used in the current Cascade Level. + int8_t current_level_known_bits; // The number of known UID bits in the current Cascade Level. + uint8_t buffer[9]; // The SELECT/ANTICOLLISION commands uses a 7 uint8_t standard frame + 2 uint8_ts CRC_A + uint8_t buffer_used; // The number of uint8_ts used in the buffer, ie the number of uint8_ts to transfer to the FIFO. + uint8_t rx_align; // Used in BitFramingReg. Defines the bit position for the first bit received. + uint8_t tx_last_bits; // Used in BitFramingReg. The number of valid bits in the last transmitted uint8_t. + uint8_t *response_buffer; + uint8_t response_length; + + // Description of buffer structure: + // uint8_t 0: SEL Indicates the Cascade Level: PICC_CMD_SEL_CL1, PICC_CMD_SEL_CL2 or PICC_CMD_SEL_CL3 + // uint8_t 1: NVB Number of Valid Bits (in complete command, not just the UID): High nibble: complete + // uint8_ts, + // Low nibble: Extra bits. uint8_t 2: UID-data or CT See explanation below. CT means Cascade Tag. uint8_t + // 3: UID-data uint8_t 4: UID-data uint8_t 5: UID-data uint8_t 6: BCC Block Check Character - XOR of + // uint8_ts 2-5 uint8_t 7: CRC_A uint8_t 8: CRC_A The BCC and CRC_A are only transmitted if we know all the UID bits + // of the current Cascade Level. + // + // Description of uint8_ts 2-5: (Section 6.5.4 of the ISO/IEC 14443-3 draft: UID contents and cascade levels) + // UID size Cascade level uint8_t2 uint8_t3 uint8_t4 uint8_t5 + // ======== ============= ===== ===== ===== ===== + // 4 uint8_ts 1 uid0 uid1 uid2 uid3 + // 7 uint8_ts 1 CT uid0 uid1 uid2 + // 2 uid3 uid4 uid5 uid6 + // 10 uint8_ts 1 CT uid0 uid1 uid2 + // 2 CT uid3 uid4 uid5 + // 3 uid6 uid7 uid8 uid9 + + // Sanity checks + if (valid_bits > 80) { + return STATUS_INVALID; + } + + ESP_LOGVV(TAG, "picc_select_(&, %d)", valid_bits); + + // Prepare MFRC522 + pcd_clear_register_bit_mask_(COLL_REG, 0x80); // ValuesAfterColl=1 => Bits received after collision are cleared. + + // Repeat Cascade Level loop until we have a complete UID. + uid_complete = false; + while (!uid_complete) { + // Set the Cascade Level in the SEL uint8_t, find out if we need to use the Cascade Tag in uint8_t 2. + switch (cascade_level) { + case 1: + buffer[0] = PICC_CMD_SEL_CL1; + uid_index = 0; + use_cascade_tag = valid_bits && uid->size > 4; // When we know that the UID has more than 4 uint8_ts + break; + + case 2: + buffer[0] = PICC_CMD_SEL_CL2; + uid_index = 3; + use_cascade_tag = valid_bits && uid->size > 7; // When we know that the UID has more than 7 uint8_ts + break; + + case 3: + buffer[0] = PICC_CMD_SEL_CL3; + uid_index = 6; + use_cascade_tag = false; // Never used in CL3. + break; + + default: + return STATUS_INTERNAL_ERROR; + break; + } + + // How many UID bits are known in this Cascade Level? + current_level_known_bits = valid_bits - (8 * uid_index); + if (current_level_known_bits < 0) { + current_level_known_bits = 0; + } + // Copy the known bits from uid->uiduint8_t[] to buffer[] + index = 2; // destination index in buffer[] + if (use_cascade_tag) { + buffer[index++] = PICC_CMD_CT; + } + uint8_t uint8_ts_to_copy = current_level_known_bits / 8 + + (current_level_known_bits % 8 + ? 1 + : 0); // The number of uint8_ts needed to represent the known bits for this level. + if (uint8_ts_to_copy) { + uint8_t maxuint8_ts = + use_cascade_tag ? 3 : 4; // Max 4 uint8_ts in each Cascade Level. Only 3 left if we use the Cascade Tag + if (uint8_ts_to_copy > maxuint8_ts) { + uint8_ts_to_copy = maxuint8_ts; + } + for (count = 0; count < uint8_ts_to_copy; count++) { + buffer[index++] = uid->uiduint8_t[uid_index + count]; + } + } + // Now that the data has been copied we need to include the 8 bits in CT in currentLevelKnownBits + if (use_cascade_tag) { + current_level_known_bits += 8; + } + + // Repeat anti collision loop until we can transmit all UID bits + BCC and receive a SAK - max 32 iterations. + select_done = false; + while (!select_done) { + // Find out how many bits and uint8_ts to send and receive. + if (current_level_known_bits >= 32) { // All UID bits in this Cascade Level are known. This is a SELECT. + + if (response_length < 4) { + ESP_LOGW(TAG, "Not enough data received."); + return STATUS_INVALID; + } + + // Serial.print(F("SELECT: currentLevelKnownBits=")); Serial.println(currentLevelKnownBits, DEC); + buffer[1] = 0x70; // NVB - Number of Valid Bits: Seven whole uint8_ts + // Calculate BCC - Block Check Character + buffer[6] = buffer[2] ^ buffer[3] ^ buffer[4] ^ buffer[5]; + // Calculate CRC_A + result = pcd_calculate_crc_(buffer, 7, &buffer[7]); + if (result != STATUS_OK) { + return result; + } + tx_last_bits = 0; // 0 => All 8 bits are valid. + buffer_used = 9; + // Store response in the last 3 uint8_ts of buffer (BCC and CRC_A - not needed after tx) + response_buffer = &buffer[6]; + response_length = 3; + } else { // This is an ANTICOLLISION. + // Serial.print(F("ANTICOLLISION: currentLevelKnownBits=")); Serial.println(currentLevelKnownBits, DEC); + tx_last_bits = current_level_known_bits % 8; + count = current_level_known_bits / 8; // Number of whole uint8_ts in the UID part. + index = 2 + count; // Number of whole uint8_ts: SEL + NVB + UIDs + buffer[1] = (index << 4) + tx_last_bits; // NVB - Number of Valid Bits + buffer_used = index + (tx_last_bits ? 1 : 0); + // Store response in the unused part of buffer + response_buffer = &buffer[index]; + response_length = sizeof(buffer) - index; + } + + // Set bit adjustments + rx_align = tx_last_bits; // Having a separate variable is overkill. But it makes the next line easier to read. + pcd_write_register_( + BIT_FRAMING_REG, + (rx_align << 4) + tx_last_bits); // RxAlign = BitFramingReg[6..4]. TxLastBits = BitFramingReg[2..0] + + // Transmit the buffer and receive the response. + result = pcd_transceive_data_(buffer, buffer_used, response_buffer, &response_length, &tx_last_bits, rx_align); + if (result == STATUS_COLLISION) { // More than one PICC in the field => collision. + uint8_t value_of_coll_reg = pcd_read_register_( + COLL_REG); // CollReg[7..0] bits are: ValuesAfterColl reserved CollPosNotValid CollPos[4:0] + if (value_of_coll_reg & 0x20) { // CollPosNotValid + return STATUS_COLLISION; // Without a valid collision position we cannot continue + } + uint8_t collision_pos = value_of_coll_reg & 0x1F; // Values 0-31, 0 means bit 32. + if (collision_pos == 0) { + collision_pos = 32; + } + if (collision_pos <= current_level_known_bits) { // No progress - should not happen + return STATUS_INTERNAL_ERROR; + } + // Choose the PICC with the bit set. + current_level_known_bits = collision_pos; + count = current_level_known_bits % 8; // The bit to modify + check_bit = (current_level_known_bits - 1) % 8; + index = 1 + (current_level_known_bits / 8) + (count ? 1 : 0); // First uint8_t is index 0. + if (response_length > 2) // Note: Otherwise buffer[index] might be not initialized + buffer[index] |= (1 << check_bit); + } else if (result != STATUS_OK) { + return result; + } else { // STATUS_OK + if (current_level_known_bits >= 32) { // This was a SELECT. + select_done = true; // No more anticollision + // We continue below outside the while. + } else { // This was an ANTICOLLISION. + // We now have all 32 bits of the UID in this Cascade Level + current_level_known_bits = 32; + // Run loop again to do the SELECT. + } + } + } // End of while (!selectDone) + + // We do not check the CBB - it was constructed by us above. + + // Copy the found UID uint8_ts from buffer[] to uid->uiduint8_t[] + index = (buffer[2] == PICC_CMD_CT) ? 3 : 2; // source index in buffer[] + uint8_ts_to_copy = (buffer[2] == PICC_CMD_CT) ? 3 : 4; + for (count = 0; count < uint8_ts_to_copy; count++) { + uid->uiduint8_t[uid_index + count] = buffer[index++]; + } + + // Check response SAK (Select Acknowledge) + if (response_length != 3 || tx_last_bits != 0) { // SAK must be exactly 24 bits (1 uint8_t + CRC_A). + return STATUS_ERROR; + } + // Verify CRC_A - do our own calculation and store the control in buffer[2..3] - those uint8_ts are not needed + // anymore. + result = pcd_calculate_crc_(response_buffer, 1, &buffer[2]); + if (result != STATUS_OK) { + return result; + } + if ((buffer[2] != response_buffer[1]) || (buffer[3] != response_buffer[2])) { + return STATUS_CRC_WRONG; + } + if (response_buffer[0] & 0x04) { // Cascade bit set - UID not complete yes + cascade_level++; + } else { + uid_complete = true; + uid->sak = response_buffer[0]; + } + } // End of while (!uidComplete) + + // Set correct uid->size + uid->size = 3 * cascade_level + 1; + + return STATUS_OK; +} + +bool RC522BinarySensor::process(const uint8_t *data, uint8_t len) { + if (len != this->uid_.size()) + return false; + + for (uint8_t i = 0; i < len; i++) { + if (data[i] != this->uid_[i]) + return false; + } + + this->publish_state(true); + this->found_ = true; + return true; +} +void RC522Trigger::process(const uint8_t *uid, uint8_t uid_length) { + char buf[32]; + format_uid(buf, uid, uid_length); + this->trigger(std::string(buf)); +} + +} // namespace rc522_spi +} // namespace esphome diff --git a/esphome/components/rc522_spi/rc522_spi.h b/esphome/components/rc522_spi/rc522_spi.h new file mode 100644 index 0000000000..51d0a9cb69 --- /dev/null +++ b/esphome/components/rc522_spi/rc522_spi.h @@ -0,0 +1,301 @@ +/** + * Library based on https://github.com/miguelbalboa/rfid + * and adapted to ESPHome by @glmnet + * + * original authors Dr.Leong, Miguel Balboa, Søren Thing Andersen, Tom Clement, many more! See GitLog. + * + * + */ + +#pragma once + +#include "esphome/core/component.h" +#include "esphome/core/automation.h" +#include "esphome/components/binary_sensor/binary_sensor.h" +#include "esphome/components/spi/spi.h" + +namespace esphome { +namespace rc522_spi { + +class RC522BinarySensor; +class RC522Trigger; + +class RC522 : public PollingComponent, + public spi::SPIDevice { + public: + void setup() override; + + void dump_config() override; + + void update() override; + float get_setup_priority() const override { return setup_priority::DATA; }; + + void loop() override; + + void register_tag(RC522BinarySensor *tag) { this->binary_sensors_.push_back(tag); } + void register_trigger(RC522Trigger *trig) { this->triggers_.push_back(trig); } + + void set_reset_pin(GPIOPin *reset) { this->reset_pin_ = reset; } + + protected: + enum PcdRegister : uint8_t { + // Page 0: Command and status + // 0x00 // reserved for future use + COMMAND_REG = 0x01 << 1, // starts and stops command execution + COM_I_EN_REG = 0x02 << 1, // enable and disable interrupt request control bits + DIV_I_EN_REG = 0x03 << 1, // enable and disable interrupt request control bits + COM_IRQ_REG = 0x04 << 1, // interrupt request bits + DIV_IRQ_REG = 0x05 << 1, // interrupt request bits + ERROR_REG = 0x06 << 1, // error bits showing the error status of the last command executed + STATUS1_REG = 0x07 << 1, // communication status bits + STATUS2_REG = 0x08 << 1, // receiver and transmitter status bits + FIFO_DATA_REG = 0x09 << 1, // input and output of 64 uint8_t FIFO buffer + FIFO_LEVEL_REG = 0x0A << 1, // number of uint8_ts stored in the FIFO buffer + WATER_LEVEL_REG = 0x0B << 1, // level for FIFO underflow and overflow warning + CONTROL_REG = 0x0C << 1, // miscellaneous control registers + BIT_FRAMING_REG = 0x0D << 1, // adjustments for bit-oriented frames + COLL_REG = 0x0E << 1, // bit position of the first bit-collision detected on the RF interface + // 0x0F // reserved for future use + + // Page 1: Command + // 0x10 // reserved for future use + MODE_REG = 0x11 << 1, // defines general modes for transmitting and receiving + TX_MODE_REG = 0x12 << 1, // defines transmission data rate and framing + RX_MODE_REG = 0x13 << 1, // defines reception data rate and framing + TX_CONTROL_REG = 0x14 << 1, // controls the logical behavior of the antenna driver pins TX1 and TX2 + TX_ASK_REG = 0x15 << 1, // controls the setting of the transmission modulation + TX_SEL_REG = 0x16 << 1, // selects the internal sources for the antenna driver + RX_SEL_REG = 0x17 << 1, // selects internal receiver settings + RX_THRESHOLD_REG = 0x18 << 1, // selects thresholds for the bit decoder + DEMOD_REG = 0x19 << 1, // defines demodulator settings + // 0x1A // reserved for future use + // 0x1B // reserved for future use + MF_TX_REG = 0x1C << 1, // controls some MIFARE communication transmit parameters + MF_RX_REG = 0x1D << 1, // controls some MIFARE communication receive parameters + // 0x1E // reserved for future use + SERIAL_SPEED_REG = 0x1F << 1, // selects the speed of the serial UART interface + + // Page 2: Configuration + // 0x20 // reserved for future use + CRC_RESULT_REG_H = 0x21 << 1, // shows the MSB and LSB values of the CRC calculation + CRC_RESULT_REG_L = 0x22 << 1, + // 0x23 // reserved for future use + MOD_WIDTH_REG = 0x24 << 1, // controls the ModWidth setting? + // 0x25 // reserved for future use + RF_CFG_REG = 0x26 << 1, // configures the receiver gain + GS_N_REG = 0x27 << 1, // selects the conductance of the antenna driver pins TX1 and TX2 for modulation + CW_GS_P_REG = 0x28 << 1, // defines the conductance of the p-driver output during periods of no modulation + MOD_GS_P_REG = 0x29 << 1, // defines the conductance of the p-driver output during periods of modulation + T_MODE_REG = 0x2A << 1, // defines settings for the internal timer + T_PRESCALER_REG = 0x2B << 1, // the lower 8 bits of the TPrescaler value. The 4 high bits are in TModeReg. + T_RELOAD_REG_H = 0x2C << 1, // defines the 16-bit timer reload value + T_RELOAD_REG_L = 0x2D << 1, + T_COUNTER_VALUE_REG_H = 0x2E << 1, // shows the 16-bit timer value + T_COUNTER_VALUE_REG_L = 0x2F << 1, + + // Page 3: Test Registers + // 0x30 // reserved for future use + TEST_SEL1_REG = 0x31 << 1, // general test signal configuration + TEST_SEL2_REG = 0x32 << 1, // general test signal configuration + TEST_PIN_EN_REG = 0x33 << 1, // enables pin output driver on pins D1 to D7 + TEST_PIN_VALUE_REG = 0x34 << 1, // defines the values for D1 to D7 when it is used as an I/O bus + TEST_BUS_REG = 0x35 << 1, // shows the status of the internal test bus + AUTO_TEST_REG = 0x36 << 1, // controls the digital self-test + VERSION_REG = 0x37 << 1, // shows the software version + ANALOG_TEST_REG = 0x38 << 1, // controls the pins AUX1 and AUX2 + TEST_DA_C1_REG = 0x39 << 1, // defines the test value for TestDAC1 + TEST_DA_C2_REG = 0x3A << 1, // defines the test value for TestDAC2 + TEST_ADC_REG = 0x3B << 1 // shows the value of ADC I and Q channels + // 0x3C // reserved for production tests + // 0x3D // reserved for production tests + // 0x3E // reserved for production tests + // 0x3F // reserved for production tests + }; + + // MFRC522 commands. Described in chapter 10 of the datasheet. + enum PcdCommand : uint8_t { + PCD_IDLE = 0x00, // no action, cancels current command execution + PCD_MEM = 0x01, // stores 25 uint8_ts into the internal buffer + PCD_GENERATE_RANDOM_ID = 0x02, // generates a 10-uint8_t random ID number + PCD_CALC_CRC = 0x03, // activates the CRC coprocessor or performs a self-test + PCD_TRANSMIT = 0x04, // transmits data from the FIFO buffer + PCD_NO_CMD_CHANGE = 0x07, // no command change, can be used to modify the CommandReg register bits without + // affecting the command, for example, the PowerDown bit + PCD_RECEIVE = 0x08, // activates the receiver circuits + PCD_TRANSCEIVE = + 0x0C, // transmits data from FIFO buffer to antenna and automatically activates the receiver after transmission + PCD_MF_AUTHENT = 0x0E, // performs the MIFARE standard authentication as a reader + PCD_SOFT_RESET = 0x0F // resets the MFRC522 + }; + + // Commands sent to the PICC. + enum PiccCommand : uint8_t { + // The commands used by the PCD to manage communication with several PICCs (ISO 14443-3, Type A, section 6.4) + PICC_CMD_REQA = 0x26, // REQuest command, Type A. Invites PICCs in state IDLE to go to READY and prepare for + // anticollision or selection. 7 bit frame. + PICC_CMD_WUPA = 0x52, // Wake-UP command, Type A. Invites PICCs in state IDLE and HALT to go to READY(*) and + // prepare for anticollision or selection. 7 bit frame. + PICC_CMD_CT = 0x88, // Cascade Tag. Not really a command, but used during anti collision. + PICC_CMD_SEL_CL1 = 0x93, // Anti collision/Select, Cascade Level 1 + PICC_CMD_SEL_CL2 = 0x95, // Anti collision/Select, Cascade Level 2 + PICC_CMD_SEL_CL3 = 0x97, // Anti collision/Select, Cascade Level 3 + PICC_CMD_HLTA = 0x50, // HaLT command, Type A. Instructs an ACTIVE PICC to go to state HALT. + PICC_CMD_RATS = 0xE0, // Request command for Answer To Reset. + // The commands used for MIFARE Classic (from http://www.mouser.com/ds/2/302/MF1S503x-89574.pdf, Section 9) + // Use PCD_MFAuthent to authenticate access to a sector, then use these commands to read/write/modify the blocks on + // the sector. + // The read/write commands can also be used for MIFARE Ultralight. + PICC_CMD_MF_AUTH_KEY_A = 0x60, // Perform authentication with Key A + PICC_CMD_MF_AUTH_KEY_B = 0x61, // Perform authentication with Key B + PICC_CMD_MF_READ = + 0x30, // Reads one 16 uint8_t block from the authenticated sector of the PICC. Also used for MIFARE Ultralight. + PICC_CMD_MF_WRITE = 0xA0, // Writes one 16 uint8_t block to the authenticated sector of the PICC. Called + // "COMPATIBILITY WRITE" for MIFARE Ultralight. + PICC_CMD_MF_DECREMENT = + 0xC0, // Decrements the contents of a block and stores the result in the internal data register. + PICC_CMD_MF_INCREMENT = + 0xC1, // Increments the contents of a block and stores the result in the internal data register. + PICC_CMD_MF_RESTORE = 0xC2, // Reads the contents of a block into the internal data register. + PICC_CMD_MF_TRANSFER = 0xB0, // Writes the contents of the internal data register to a block. + // The commands used for MIFARE Ultralight (from http://www.nxp.com/documents/data_sheet/MF0ICU1.pdf, Section 8.6) + // The PICC_CMD_MF_READ and PICC_CMD_MF_WRITE can also be used for MIFARE Ultralight. + PICC_CMD_UL_WRITE = 0xA2 // Writes one 4 uint8_t page to the PICC. + }; + + // Return codes from the functions in this class. Remember to update GetStatusCodeName() if you add more. + // last value set to 0xff, then compiler uses less ram, it seems some optimisations are triggered + enum StatusCode : uint8_t { + STATUS_OK, // Success + STATUS_ERROR, // Error in communication + STATUS_COLLISION, // Collission detected + STATUS_TIMEOUT, // Timeout in communication. + STATUS_NO_ROOM, // A buffer is not big enough. + STATUS_INTERNAL_ERROR, // Internal error in the code. Should not happen ;-) + STATUS_INVALID, // Invalid argument. + STATUS_CRC_WRONG, // The CRC_A does not match + STATUS_MIFARE_NACK = 0xff // A MIFARE PICC responded with NAK. + }; + + // A struct used for passing the UID of a PICC. + using Uid = struct { + uint8_t size; // Number of uint8_ts in the UID. 4, 7 or 10. + uint8_t uiduint8_t[10]; + uint8_t sak; // The SAK (Select acknowledge) uint8_t returned from the PICC after successful selection. + }; + + Uid uid_; + uint32_t update_wait_{0}; + + void pcd_reset_(); + void initialize_(); + void pcd_antenna_on_(); + uint8_t pcd_read_register_(PcdRegister reg ///< The register to read from. One of the PCD_Register enums. + ); + + /** + * Reads a number of uint8_ts from the specified register in the MFRC522 chip. + * The interface is described in the datasheet section 8.1.2. + */ + void pcd_read_register_(PcdRegister reg, ///< The register to read from. One of the PCD_Register enums. + uint8_t count, ///< The number of uint8_ts to read + uint8_t *values, ///< uint8_t array to store the values in. + uint8_t rx_align ///< Only bit positions rxAlign..7 in values[0] are updated. + ); + void pcd_write_register_(PcdRegister reg, ///< The register to write to. One of the PCD_Register enums. + uint8_t value ///< The value to write. + ); + + /** + * Writes a number of uint8_ts to the specified register in the MFRC522 chip. + * The interface is described in the datasheet section 8.1.2. + */ + void pcd_write_register_(PcdRegister reg, ///< The register to write to. One of the PCD_Register enums. + uint8_t count, ///< The number of uint8_ts to write to the register + uint8_t *values ///< The values to write. uint8_t array. + ); + + StatusCode picc_request_a_( + uint8_t *buffer_atqa, ///< The buffer to store the ATQA (Answer to request) in + uint8_t *buffer_size ///< Buffer size, at least two uint8_ts. Also number of uint8_ts returned if STATUS_OK. + ); + StatusCode picc_reqa_or_wupa_( + uint8_t command, ///< The command to send - PICC_CMD_REQA or PICC_CMD_WUPA + uint8_t *buffer_atqa, ///< The buffer to store the ATQA (Answer to request) in + uint8_t *buffer_size ///< Buffer size, at least two uint8_ts. Also number of uint8_ts returned if STATUS_OK. + ); + void pcd_set_register_bit_mask_(PcdRegister reg, ///< The register to update. One of the PCD_Register enums. + uint8_t mask ///< The bits to set. + ); + void pcd_clear_register_bit_mask_(PcdRegister reg, ///< The register to update. One of the PCD_Register enums. + uint8_t mask ///< The bits to clear. + ); + + StatusCode pcd_transceive_data_(uint8_t *send_data, uint8_t send_len, uint8_t *back_data, uint8_t *back_len, + uint8_t *valid_bits = nullptr, uint8_t rx_align = 0, bool check_crc = false); + StatusCode pcd_communicate_with_picc_(uint8_t command, uint8_t wait_i_rq, uint8_t *send_data, uint8_t send_len, + uint8_t *back_data = nullptr, uint8_t *back_len = nullptr, + uint8_t *valid_bits = nullptr, uint8_t rx_align = 0, bool check_crc = false); + StatusCode pcd_calculate_crc_( + uint8_t *data, ///< In: Pointer to the data to transfer to the FIFO for CRC calculation. + uint8_t length, ///< In: The number of uint8_ts to transfer. + uint8_t *result ///< Out: Pointer to result buffer. Result is written to result[0..1], low uint8_t first. + ); + RC522::StatusCode picc_is_new_card_present_(); + bool picc_read_card_serial_(); + StatusCode picc_select_( + Uid *uid, ///< Pointer to Uid struct. Normally output, but can also be used to supply a known UID. + uint8_t valid_bits = 0 ///< The number of known UID bits supplied in *uid. Normally 0. If set you must also + ///< supply uid->size. + ); + + /** Read a data frame from the RC522 and return the result as a vector. + * + * Note that is_ready needs to be checked first before requesting this method. + * + * On failure, an empty vector is returned. + */ + std::vector r_c522_read_data_(); + + GPIOPin *reset_pin_{nullptr}; + uint8_t reset_count_{0}; + uint32_t reset_timeout_{0}; + bool initialize_pending_{false}; + std::vector binary_sensors_; + std::vector triggers_; + + enum RC522Error { + NONE = 0, + RESET_FAILED, + } error_code_{NONE}; +}; + +class RC522BinarySensor : public binary_sensor::BinarySensor { + public: + void set_uid(const std::vector &uid) { uid_ = uid; } + + bool process(const uint8_t *data, uint8_t len); + + void on_scan_end() { + if (!this->found_) { + this->publish_state(false); + } + this->found_ = false; + } + + protected: + std::vector uid_; + bool found_{false}; +}; + +class RC522Trigger : public Trigger { + public: + void process(const uint8_t *uid, uint8_t uid_length); +}; + +#ifndef MFRC522_SPICLOCK +#define MFRC522_SPICLOCK SPI_CLOCK_DIV4 // MFRC522 accept upto 10MHz +#endif + +} // namespace rc522_spi +} // namespace esphome diff --git a/script/build_codeowners.py b/script/build_codeowners.py index fce59b3b95..f21e9ca2a5 100755 --- a/script/build_codeowners.py +++ b/script/build_codeowners.py @@ -48,6 +48,10 @@ for path in components_dir.iterdir(): name = path.name comp = get_component(name) + if comp is None: + print(f'Cannot find component {name}. Make sure current path is pip installed ESPHome') + sys.exit(1) + codeowners[f'esphome/components/{name}/*'].extend(comp.codeowners) for platform_path in path.iterdir(): diff --git a/tests/test1.yaml b/tests/test1.yaml index 732d532bdf..6a2f95c355 100644 --- a/tests/test1.yaml +++ b/tests/test1.yaml @@ -1657,6 +1657,13 @@ pn532: rdm6300: +rc522_spi: + cs_pin: GPIO23 + update_interval: 1s + on_tag: + - lambda: |- + ESP_LOGD("main", "Found tag %s", x.c_str()); + gps: time: