2018-03-28 20:37:58 -03:00
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/*
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <AP_HAL/AP_HAL.h>
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#include "AP_EFI_Serial_MS.h"
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#if EFI_ENABLED
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#include <AP_SerialManager/AP_SerialManager.h>
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extern const AP_HAL::HAL &hal;
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AP_EFI_Serial_MS::AP_EFI_Serial_MS(AP_EFI &_frontend):
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AP_EFI_Backend(_frontend)
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{
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internal_state.estimated_consumed_fuel_volume_cm3 = 0; // Just to be sure
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port = AP::serialmanager().find_serial(AP_SerialManager::SerialProtocol_EFI_MS, 0);
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}
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void AP_EFI_Serial_MS::update()
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{
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if (!port) {
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return;
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}
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uint32_t now = AP_HAL::millis();
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const uint32_t expected_bytes = 2 + (RT_LAST_OFFSET - RT_FIRST_OFFSET) + 4;
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if (port->available() >= expected_bytes && read_incoming_realtime_data()) {
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last_response_ms = now;
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copy_to_frontend();
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}
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if (port->available() == 0 || now - last_response_ms > 200) {
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2020-05-22 21:24:32 -03:00
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port->discard_input();
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2018-03-28 20:37:58 -03:00
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// Request an update from the realtime table (7).
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// The data we need start at offset 6 and ends at 129
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send_request(7, RT_FIRST_OFFSET, RT_LAST_OFFSET);
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}
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}
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bool AP_EFI_Serial_MS::read_incoming_realtime_data()
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{
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// Data is parsed directly from the buffer, otherwise we would need to allocate
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// several hundred bytes for the entire realtime data table or request every
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// value individiually
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uint16_t message_length = 0;
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// reset checksum before reading new data
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checksum = 0;
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// Message length field begins the message (16 bits, excluded from CRC calculation)
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// Message length value excludes the message length and CRC bytes
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message_length = port->read() << 8;
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message_length += port->read();
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if (message_length >= 256) {
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// don't process invalid messages
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// hal.console->printf("message_length: %u\n", message_length);
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return false;
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}
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// Response Flag (see "response_codes" enum)
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response_flag = read_byte_CRC32();
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if (response_flag != RESPONSE_WRITE_OK) {
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// abort read if we did not receive the correct response code;
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return false;
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}
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// Iterate over the payload bytes
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for ( uint8_t offset=RT_FIRST_OFFSET; offset < (RT_FIRST_OFFSET + message_length - 1); offset++) {
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uint8_t data = read_byte_CRC32();
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float temp_float;
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switch (offset) {
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case PW1_MSB:
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internal_state.cylinder_status[0].injection_time_ms = (float)((data << 8) + read_byte_CRC32())/1000.0f;
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offset++; // increment the counter because we read a byte in the previous line
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break;
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case RPM_MSB:
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// Read 16 bit RPM
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internal_state.engine_speed_rpm = (data << 8) + read_byte_CRC32();
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offset++;
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break;
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case ADVANCE_MSB:
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internal_state.cylinder_status[0].ignition_timing_deg = (float)((data << 8) + read_byte_CRC32())/10.0f;
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offset++;
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break;
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case ENGINE_BM:
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break;
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case BAROMETER_MSB:
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internal_state.atmospheric_pressure_kpa = (float)((data << 8) + read_byte_CRC32())/10.0f;
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offset++;
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break;
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case MAP_MSB:
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internal_state.intake_manifold_pressure_kpa = (float)((data << 8) + read_byte_CRC32())/10.0f;
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offset++;
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break;
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case MAT_MSB:
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temp_float = (float)((data << 8) + read_byte_CRC32())/10.0f;
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offset++;
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internal_state.intake_manifold_temperature = f_to_k(temp_float);
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break;
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case CHT_MSB:
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temp_float = (float)((data << 8) + read_byte_CRC32())/10.0f;
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offset++;
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internal_state.cylinder_status[0].cylinder_head_temperature = f_to_k(temp_float);
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break;
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case TPS_MSB:
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temp_float = (float)((data << 8) + read_byte_CRC32())/10.0f;
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offset++;
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internal_state.throttle_position_percent = roundf(temp_float);
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break;
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case AFR1_MSB:
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temp_float = (float)((data << 8) + read_byte_CRC32())/10.0f;
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offset++;
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internal_state.cylinder_status[0].lambda_coefficient = temp_float;
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break;
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case DWELL_MSB:
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temp_float = (float)((data << 8) + read_byte_CRC32())/10.0f;
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internal_state.spark_dwell_time_ms = temp_float;
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offset++;
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break;
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case LOAD:
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internal_state.engine_load_percent = data;
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break;
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case FUEL_PRESSURE_MSB:
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// MS Fuel Pressure is unitless, store as KPA anyway
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temp_float = (float)((data << 8) + read_byte_CRC32());
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internal_state.fuel_pressure = temp_float;
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offset++;
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break;
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}
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}
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// Read the four CRC bytes
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uint32_t received_CRC;
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received_CRC = port->read() << 24;
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received_CRC += port->read() << 16;
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received_CRC += port->read() << 8;
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received_CRC += port->read();
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if (received_CRC != checksum) {
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// hal.console->printf("EFI CRC: 0x%08x 0x%08x\n", received_CRC, checksum);
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return false;
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}
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// Calculate Fuel Consumption
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// Duty Cycle (Percent, because that's how HFE gives us the calibration coefficients)
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float duty_cycle = (internal_state.cylinder_status[0].injection_time_ms * internal_state.engine_speed_rpm)/600.0f;
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uint32_t current_time = AP_HAL::millis();
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// Super Simplified integration method - Error Analysis TBD
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// This calcualtion gives erroneous results when the engine isn't running
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if (internal_state.engine_speed_rpm > RPM_THRESHOLD) {
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internal_state.fuel_consumption_rate_cm3pm = duty_cycle*get_coef1() - get_coef2();
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internal_state.estimated_consumed_fuel_volume_cm3 += internal_state.fuel_consumption_rate_cm3pm * (current_time - internal_state.last_updated_ms)/60000.0f;
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} else {
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internal_state.fuel_consumption_rate_cm3pm = 0;
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}
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internal_state.last_updated_ms = current_time;
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return true;
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}
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void AP_EFI_Serial_MS::send_request(uint8_t table, uint16_t first_offset, uint16_t last_offset)
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{
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uint16_t length = last_offset - first_offset + 1;
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// Fixed message size (0x0007)
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// Command 'r' (0x72)
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// Null CANid (0x00)
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const uint8_t data[9] = {
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0x00,
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0x07,
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0x72,
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0x00,
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(uint8_t)table,
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(uint8_t)(first_offset >> 8),
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(uint8_t)(first_offset),
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(uint8_t)(length >> 8),
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(uint8_t)(length)
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};
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uint32_t crc = 0;
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// Write the request and calc CRC
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for (uint8_t i = 0; i != sizeof(data) ; i++) {
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// Message size is excluded from CRC
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if (i > 1) {
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crc = CRC32_compute_byte(crc, data[i]);
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}
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port->write(data[i]);
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}
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// Write the CRC32
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port->write((uint8_t)(crc >> 24));
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port->write((uint8_t)(crc >> 16));
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port->write((uint8_t)(crc >> 8));
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port->write((uint8_t)crc);
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}
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uint8_t AP_EFI_Serial_MS::read_byte_CRC32()
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{
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// Read a byte and update the CRC
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uint8_t data = port->read();
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checksum = CRC32_compute_byte(checksum, data);
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return data;
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}
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// CRC32 matching MegaSquirt
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uint32_t AP_EFI_Serial_MS::CRC32_compute_byte(uint32_t crc, uint8_t data)
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{
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crc ^= ~0U;
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crc = crc_crc32(crc, &data, 1);
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crc ^= ~0U;
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return crc;
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}
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#endif // EFI_ENABLED
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