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DShotRMT/DShotRMT.cpp

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/**
* @file DShotRMT.cpp
* @brief DShot signal generation using ESP32 RMT with bidirectional support
* @author Wastl Kraus
* @date 2025-06-11
* @license MIT
*/
#include "DShotRMT.h"
// --- DShot Timings ---
// frame_length_us, ticks_per_bit, ticks_one_high, ticks_zero_high, ticks_zero_low, ticks_one_low
constexpr dshot_timing_t DSHOT_TIMINGS[] = {
{0, 0, 0, 0, 0, 0}, // DSHOT_OFF
{128, 64, 48, 24, 40, 16}, // DSHOT150
{64, 32, 24, 12, 20, 8}, // DSHOT300
{32, 16, 12, 6, 10, 4}, // DSHOT600
{16, 8, 6, 3, 5, 2} // DSHOT1200
};
//
DShotRMT::DShotRMT(gpio_num_t gpio, dshot_mode_t mode, bool is_bidirectional):
_gpio(gpio),
_mode(mode),
_is_bidirectional(is_bidirectional),
_timing_config(DSHOT_TIMINGS[mode]),
_rmt_tx_channel(nullptr),
_rmt_rx_channel(nullptr),
_dshot_encoder(nullptr),
_last_erpm(0),
_last_transmission_time(0),
_current_packet(0)
{
// Double up frame time for bidirectional mode
if (_is_bidirectional)
{
_frame_time_us = (_timing_config.frame_length_us << 1) + DSHOT_SWITCH_TIME;
}
// Calculate frame time including switch time
_frame_time_us = _timing_config.frame_length_us + DSHOT_SWITCH_TIME;
}
// Init DShotRMT
bool DShotRMT::begin()
{
// Init TX Channel
if (!_initTXChannel())
{
Serial.println(DSHOT_MSG_01);
return DSHOT_ERROR;
}
// Init RX Channel
if (!_initRXChannel() && _is_bidirectional)
{
Serial.println(DSHOT_MSG_02);
return DSHOT_ERROR;
}
// Init DShot Decoder
if (!_initDShotEncoder())
{
Serial.println(DSHOT_MSG_03);
return DSHOT_ERROR;
}
// All good, ready
return DSHOT_OK;
}
//
bool DShotRMT::setThrottle(uint16_t throttle)
{
// Precheck throttle value
if (throttle < DSHOT_THROTTLE_MIN || throttle > DSHOT_THROTTLE_MAX)
{
Serial.println(DSHOT_MSG_06);
return DSHOT_ERROR;
}
//
dshot_packet_t packet = _buildDShotPacket(throttle);
return (_sendDShotFrame(packet));
}
//
bool DShotRMT::sendDShotCommand(uint16_t command)
{
// Precheck command value
if (command < DSHOT_CMD_MOTOR_STOP || command > DSHOT_CMD_MAX)
{
Serial.println(DSHOT_MSG_07);
return DSHOT_ERROR;
}
//
dshot_packet_t packet = _buildDShotPacket(command);
return (_sendDShotFrame(packet));
}
//
uint16_t DShotRMT::getERPM()
{
if (!_is_bidirectional || !_rmt_rx_channel)
{
Serial.println(DSHOT_MSG_08);
return _last_erpm;
}
// Try to receive telemetry data
rmt_symbol_word_t _rx_symbols[RX_BUFFER_SIZE];
if (!rmt_receive(_rmt_rx_channel, _rx_symbols, DSHOT_SYMBOLS_SIZE, &_receive_config))
{
Serial.println(DSHOT_MSG_09);
return _last_erpm;
}
// Decode the response
uint16_t new_erpm = _decodeDShotFrame(_rx_symbols);
if (new_erpm != 0)
{
_last_erpm = new_erpm;
}
return _last_erpm;
}
//
uint32_t DShotRMT::getMotorRPM(uint8_t magnet_count)
{
uint8_t pole_pairs = max(1, magnet_count / 2);
return getERPM() / pole_pairs;
}
//
bool DShotRMT::_initTXChannel()
{
// --- RMT TX Config ---
_tx_channel_config.gpio_num = _gpio;
_tx_channel_config.clk_src = DSHOT_CLOCK_SRC_DEFAULT;
_tx_channel_config.resolution_hz = DSHOT_RMT_RESOLUTION;
_tx_channel_config.mem_block_symbols = DSHOT_SYMBOLS_SIZE;
_tx_channel_config.trans_queue_depth = TX_BUFFER_SIZE;
//
_transmit_config.loop_count = 0;
// ...it's a trap
_transmit_config.flags.eot_level = _is_bidirectional ? 1 : 0;
// Creates and activates RMT TX Channel
if (rmt_new_tx_channel(&_tx_channel_config, &_rmt_tx_channel) != DSHOT_OK)
{
return DSHOT_ERROR;
}
return (rmt_enable(_rmt_tx_channel) == 0);
}
//
bool DShotRMT::_initRXChannel()
{
// --- RMT RX Config ---
_rx_channel_config.gpio_num = _gpio;
_rx_channel_config.clk_src = DSHOT_CLOCK_SRC_DEFAULT;
_rx_channel_config.resolution_hz = DSHOT_RMT_RESOLUTION;
_rx_channel_config.mem_block_symbols = DSHOT_SYMBOLS_SIZE;
_receive_config.signal_range_min_ns = 300;
_receive_config.signal_range_max_ns = 5000;
// Creates and activates RMT TX Channel
if (rmt_new_rx_channel(&_rx_channel_config, &_rmt_rx_channel) != DSHOT_OK)
{
return DSHOT_ERROR;
}
return (rmt_enable(_rmt_rx_channel) == 0);
}
//
bool DShotRMT::_initDShotEncoder()
{
// Creates a dummy encoder
rmt_copy_encoder_config_t encoder_config = {};
return rmt_new_copy_encoder(&encoder_config, &_dshot_encoder) == 0;
}
// Use RMT to transmit a prepared DShot packet and returns it
bool DShotRMT::_sendDShotFrame(const dshot_packet_t &packet)
{
// Exclude calculation from timing is more stable
rmt_symbol_word_t tx_symbols[DSHOT_BITS_PER_FRAME];
_encodeDShotFrame(packet, tx_symbols);
// Checking timer signal
if (_timer_signal())
{
// Trigger RMT Transmit
rmt_transmit(_rmt_tx_channel, _dshot_encoder, tx_symbols, DSHOT_SYMBOLS_SIZE, &_transmit_config);
// Time Stamp
return _timer_reset();
}
return DSHOT_ERROR;
}
// Calculates checksum for given package
uint16_t DShotRMT::_calculateCRC(const dshot_packet_t &packet)
{
uint16_t data = (packet.throttle_value << 1) | packet.telemetric_request;
uint16_t crc = (data ^ (data >> 4) ^ (data >> 8)) & 0b0000000000001111;
// Invert CRC for bidirectional DShot
if (_is_bidirectional)
{
crc = (~crc) & 0b0000000000001111;
}
return crc;
}
// Returns bitwise parsed DShot packet
uint16_t DShotRMT::_parseDShotPacket(const dshot_packet_t &packet)
{
uint16_t data = (packet.throttle_value << 1) | packet.telemetric_request;
return (data << 4) | _calculateCRC(packet);
}
// Returns a "true" DShot Packet ready to roll
dshot_packet_t DShotRMT::_buildDShotPacket(const uint16_t value)
{
// DShot Frame Container
dshot_packet_t packet = {};
// Create DShot packet
packet.throttle_value = value;
packet.telemetric_request = 0;
packet.checksum = _calculateCRC(packet);
//
return packet;
}
// Encodes DShot packet into RMT buffer
bool IRAM_ATTR DShotRMT::_encodeDShotFrame(const dshot_packet_t &packet, rmt_symbol_word_t *symbols)
{
// Parse actual packet into buffer
_current_packet = _parseDShotPacket(packet);
// Convert the parsed dshot frame to rmt_tx data
for (int i = 0; i < DSHOT_BITS_PER_FRAME; i++)
{
// Encode RMT symbols bitwise (MSB first) - tricky
bool bit = (_current_packet >> (DSHOT_BITS_PER_FRAME - 1 - i)) & 0b0000000000000001;
if (_is_bidirectional)
{
symbols[i].level0 = 0;
symbols[i].duration0 = bit ? _timing_config.ticks_one_high : _timing_config.ticks_zero_high;
symbols[i].level1 = 1;
symbols[i].duration1 = bit ? _timing_config.ticks_one_low : _timing_config.ticks_zero_low;
}
else
{
symbols[i].level0 = 1;
symbols[i].duration0 = bit ? _timing_config.ticks_one_high : _timing_config.ticks_zero_high;
symbols[i].level1 = 0;
symbols[i].duration1 = bit ? _timing_config.ticks_one_low : _timing_config.ticks_zero_low;
}
}
return DSHOT_OK;
}
//
uint16_t DShotRMT::_decodeDShotFrame(const rmt_symbol_word_t *symbols)
{
uint16_t received_frame = 0;
// Decode each symbol to reconstruct the frame
for (size_t i = 0; i < DSHOT_BITS_PER_FRAME; ++i)
{
bool bit = symbols[i].duration0 < symbols[i].duration1;
received_frame = (received_frame << 1) | bit;
}
// Extract payload and CRC
uint16_t data = received_frame >> 4;
uint16_t received_crc = received_frame & 0b0000000000001111;
// Calculate CRC for received frame
uint16_t calculated_crc = (data ^ (data >> 4) ^ (data >> 8)) & 0b0000000000001111;
if (_is_bidirectional)
{
calculated_crc = (~calculated_crc) & 0b0000000000001111;
}
// Compare CRC
if (received_crc != calculated_crc)
{
Serial.println(DSHOT_MSG_04);
return 0b0000000000000000;
}
// Removes telemetry bit and returns 10bit value
return data >> 1;
}
// Timer triggered
bool DShotRMT::_timer_signal()
{
return (micros() - _last_transmission_time) >= _frame_time_us;
}
// Updates timestamp
bool DShotRMT::_timer_reset()
{
_last_transmission_time = micros();
return DSHOT_OK;
}
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