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Qurt platform custom icm42688p IMU driver (#20753)

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- first version of IMU driver for the VOXL 2 platform (Qurt)
 - this is a customized version of the Invensense ICM42688P driver, it is currently in the VOXL 2 board directory
This commit is contained in:
Eric Katzfey 2022-12-12 19:02:23 -08:00 committed by GitHub
parent 33e39d68f7
commit e17ddcc0e5
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GPG Key ID: 4AEE18F83AFDEB23
24 changed files with 2040 additions and 23 deletions
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4
boards/modalai/voxl2-slpi/src/CMakeLists.txt
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@ -34,4 +34,8 @@
add_library(drivers_board add_library(drivers_board
board_config.h board_config.h
init.c init.c
spi.cpp
) )
# Add custom drivers for SLPI
add_subdirectory(${PX4_BOARD_DIR}/src/drivers/icm42688p)

9
boards/modalai/voxl2-slpi/src/board_config.h
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@ -46,5 +46,14 @@
*/ */
#define PX4_NUMBER_I2C_BUSES 3 #define PX4_NUMBER_I2C_BUSES 3
/*
* SPI buses
*/
#define CONFIG_SPI 1
#define BOARD_SPI_BUS_MAX_BUS_ITEMS 1
/*
* Include these last to make use of the definitions above
*/
#include <system_config.h> #include <system_config.h>
#include <px4_platform_common/board_common.h> #include <px4_platform_common/board_common.h>

48
boards/modalai/voxl2-slpi/src/drivers/icm42688p/CMakeLists.txt Normal file
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@ -0,0 +1,48 @@
############################################################################
#
# Copyright (c) 2020 PX4 Development Team. All rights reserved.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions
# are met:
#
# 1. Redistributions of source code must retain the above copyright
# notice, this list of conditions and the following disclaimer.
# 2. Redistributions in binary form must reproduce the above copyright
# notice, this list of conditions and the following disclaimer in
# the documentation and/or other materials provided with the
# distribution.
# 3. Neither the name PX4 nor the names of its contributors may be
# used to endorse or promote products derived from this software
# without specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
# FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
# COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
# INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
# BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
# OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
# AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
# LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
# ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
# POSSIBILITY OF SUCH DAMAGE.
#
############################################################################
px4_add_module(
MODULE drivers__imu__invensense__icm42688p
MAIN icm42688p
COMPILE_FLAGS
${MAX_CUSTOM_OPT_LEVEL}
SRCS
icm42688p_main.cpp
ICM42688P.cpp
ICM42688P.hpp
InvenSense_ICM42688P_registers.hpp
DEPENDS
px4_work_queue
drivers_accelerometer
drivers_gyroscope
drivers__device
)

985
boards/modalai/voxl2-slpi/src/drivers/icm42688p/ICM42688P.cpp Normal file
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@ -0,0 +1,985 @@
/****************************************************************************
*
* Copyright (c) 2020 PX4 Development Team. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
#include "ICM42688P.hpp"
bool hitl_mode = false;
using namespace time_literals;
static constexpr int16_t combine(uint8_t msb, uint8_t lsb)
{
return (msb << 8u) | lsb;
}
ICM42688P::ICM42688P(const I2CSPIDriverConfig &config) :
// SPI(DRV_IMU_DEVTYPE_ICM42688P, MODULE_NAME, bus, device, spi_mode, bus_frequency),
// I2CSPIDriver(MODULE_NAME, px4::device_bus_to_wq(get_device_id()), bus_option, bus),
// _drdy_gpio(drdy_gpio)
SPI(config),
I2CSPIDriver(config),
_drdy_gpio(config.drdy_gpio),
_px4_accel(get_device_id(), config.rotation),
_px4_gyro(get_device_id(), config.rotation)
{
if (config.drdy_gpio != 0) {
_drdy_missed_perf = perf_alloc(PC_COUNT, MODULE_NAME": DRDY missed");
}
if (!hitl_mode) {
// _px4_accel = std::make_shared<PX4Accelerometer>(get_device_id(), rotation);
// _px4_gyro = std::make_shared<PX4Gyroscope>(get_device_id(), rotation);
ConfigureSampleRate(_px4_gyro.get_max_rate_hz());
// _imu_server_pub.advertise();
} else {
ConfigureSampleRate(0);
}
}
ICM42688P::~ICM42688P()
{
perf_free(_bad_register_perf);
perf_free(_bad_transfer_perf);
perf_free(_fifo_empty_perf);
perf_free(_fifo_overflow_perf);
perf_free(_fifo_reset_perf);
perf_free(_drdy_missed_perf);
// if (!hitl_mode){
// _imu_server_pub.unadvertise();
// }
}
int ICM42688P::init()
{
int ret = SPI::init();
if (ret != PX4_OK) {
DEVICE_DEBUG("SPI::init failed (%i)", ret);
return ret;
}
return Reset() ? 0 : -1;
}
bool ICM42688P::Reset()
{
_state = STATE::RESET;
DataReadyInterruptDisable();
ScheduleClear();
ScheduleNow();
return true;
}
void ICM42688P::exit_and_cleanup()
{
DataReadyInterruptDisable();
I2CSPIDriverBase::exit_and_cleanup();
}
void ICM42688P::print_status()
{
I2CSPIDriverBase::print_status();
PX4_INFO("FIFO empty interval: %d us (%.1f Hz)", _fifo_empty_interval_us, 1e6 / _fifo_empty_interval_us);
perf_print_counter(_bad_register_perf);
perf_print_counter(_bad_transfer_perf);
perf_print_counter(_fifo_empty_perf);
perf_print_counter(_fifo_overflow_perf);
perf_print_counter(_fifo_reset_perf);
perf_print_counter(_drdy_missed_perf);
}
int ICM42688P::probe()
{
for (int i = 0; i < 3; i++) {
uint8_t whoami = RegisterRead(Register::BANK_0::WHO_AM_I);
if (whoami == WHOAMI) {
PX4_INFO("ICM42688P::probe successful!");
return PX4_OK;
} else {
DEVICE_DEBUG("unexpected WHO_AM_I 0x%02x", whoami);
uint8_t reg_bank_sel = RegisterRead(Register::BANK_0::REG_BANK_SEL);
int bank = reg_bank_sel >> 4;
if (bank >= 1 && bank <= 3) {
DEVICE_DEBUG("incorrect register bank for WHO_AM_I REG_BANK_SEL:0x%02x, bank:%d", reg_bank_sel, bank);
// force bank selection and retry
SelectRegisterBank(REG_BANK_SEL_BIT::USER_BANK_0, true);
}
}
}
return PX4_ERROR;
}
void ICM42688P::RunImpl()
{
PX4_INFO(">>> ICM42688P this: %p", this);
const hrt_abstime now = hrt_absolute_time();
switch (_state) {
case STATE::RESET:
// DEVICE_CONFIG: Software reset configuration
RegisterWrite(Register::BANK_0::DEVICE_CONFIG, DEVICE_CONFIG_BIT::SOFT_RESET_CONFIG);
_reset_timestamp = now;
_failure_count = 0;
_state = STATE::WAIT_FOR_RESET;
ScheduleDelayed(2_ms); // to be safe wait 2 ms for soft reset to be effective
break;
case STATE::WAIT_FOR_RESET:
if ((RegisterRead(Register::BANK_0::WHO_AM_I) == WHOAMI)
&& (RegisterRead(Register::BANK_0::DEVICE_CONFIG) == 0x00)
&& (RegisterRead(Register::BANK_0::INT_STATUS) & INT_STATUS_BIT::RESET_DONE_INT)) {
_state = STATE::CONFIGURE;
ScheduleDelayed(10_ms); // 30 ms gyro startup time, 10 ms accel from sleep to valid data
} else {
// RESET not complete
if (hrt_elapsed_time(&_reset_timestamp) > 1000_ms) {
PX4_DEBUG("Reset failed, retrying");
_state = STATE::RESET;
ScheduleDelayed(100_ms);
} else {
PX4_DEBUG("Reset not complete, check again in 10 ms");
ScheduleDelayed(10_ms);
}
}
break;
case STATE::CONFIGURE:
if (Configure()) {
// Wakeup accel and gyro after configuring registers
ScheduleDelayed(1_ms); // add a delay here to be safe
RegisterWrite(Register::BANK_0::PWR_MGMT0, PWR_MGMT0_BIT::GYRO_MODE_LOW_NOISE | PWR_MGMT0_BIT::ACCEL_MODE_LOW_NOISE);
ScheduleDelayed(30_ms); // 30 ms gyro startup time, 10 ms accel from sleep to valid data
// if configure succeeded then start reading from FIFO
_state = STATE::FIFO_READ;
if (DataReadyInterruptConfigure()) {
_data_ready_interrupt_enabled = true;
// backup schedule as a watchdog timeout
ScheduleDelayed(100_ms);
} else {
PX4_ERR("ICM42688P::RunImpl interrupt configuration failed");
_data_ready_interrupt_enabled = false;
ScheduleOnInterval(_fifo_empty_interval_us, _fifo_empty_interval_us);
}
FIFOReset();
} else {
PX4_ERR("ICM42688P::RunImpl configuration failed");
// CONFIGURE not complete
if (hrt_elapsed_time(&_reset_timestamp) > 1000_ms) {
PX4_DEBUG("Configure failed, resetting");
_state = STATE::RESET;
} else {
PX4_DEBUG("Configure failed, retrying");
}
ScheduleDelayed(100_ms);
}
break;
case STATE::FIFO_READ: {
#ifndef __PX4_QURT
uint32_t samples = 0;
if (_data_ready_interrupt_enabled) {
// scheduled from interrupt if _drdy_fifo_read_samples was set as expected
if (_drdy_fifo_read_samples.fetch_and(0) != _fifo_gyro_samples) {
perf_count(_drdy_missed_perf);
} else {
samples = _fifo_gyro_samples;
}
// push backup schedule back
ScheduleDelayed(_fifo_empty_interval_us * 2);
}
if (samples == 0) {
// check current FIFO count
const uint16_t fifo_count = FIFOReadCount();
if (fifo_count >= FIFO::SIZE) {
FIFOReset();
perf_count(_fifo_overflow_perf);
} else if (fifo_count == 0) {
perf_count(_fifo_empty_perf);
} else {
// FIFO count (size in bytes)
samples = (fifo_count / sizeof(FIFO::DATA));
if (samples > FIFO_MAX_SAMPLES) {
// not technically an overflow, but more samples than we expected or can publish
FIFOReset();
perf_count(_fifo_overflow_perf);
samples = 0;
}
}
}
bool success = false;
if (samples >= 1) {
if (FIFORead(now, samples)) {
success = true;
if (_failure_count > 0) {
_failure_count--;
}
}
}
if (!success) {
_failure_count++;
// full reset if things are failing consistently
if (_failure_count > 10) {
Reset();
return;
}
}
// check configuration registers periodically or immediately following any failure
if (RegisterCheck(_register_bank0_cfg[_checked_register_bank0])
&& RegisterCheck(_register_bank1_cfg[_checked_register_bank1])
&& RegisterCheck(_register_bank2_cfg[_checked_register_bank2])
) {
_last_config_check_timestamp = now;
_checked_register_bank0 = (_checked_register_bank0 + 1) % size_register_bank0_cfg;
_checked_register_bank1 = (_checked_register_bank1 + 1) % size_register_bank1_cfg;
_checked_register_bank2 = (_checked_register_bank2 + 1) % size_register_bank2_cfg;
} else {
// register check failed, force reset
perf_count(_bad_register_perf);
Reset();
}
#endif
}
break;
}
}
void ICM42688P::ConfigureSampleRate(int sample_rate)
{
if (sample_rate == 0) {
sample_rate = 800; // default to 800 Hz
}
// round down to nearest FIFO sample dt
const float min_interval = FIFO_SAMPLE_DT;
_fifo_empty_interval_us = math::max(roundf((1e6f / (float)sample_rate) / min_interval) * min_interval, min_interval);
_fifo_gyro_samples = roundf(math::min((float)_fifo_empty_interval_us / (1e6f / GYRO_RATE), (float)FIFO_MAX_SAMPLES));
// recompute FIFO empty interval (us) with actual gyro sample limit
_fifo_empty_interval_us = _fifo_gyro_samples * (1e6f / GYRO_RATE);
ConfigureFIFOWatermark(_fifo_gyro_samples);
}
void ICM42688P::ConfigureFIFOWatermark(uint8_t samples)
{
// FIFO watermark threshold in number of bytes
const uint16_t fifo_watermark_threshold = samples * sizeof(FIFO::DATA);
for (auto &r : _register_bank0_cfg) {
if (r.reg == Register::BANK_0::FIFO_CONFIG2) {
// FIFO_WM[7:0] FIFO_CONFIG2
r.set_bits = fifo_watermark_threshold & 0xFF;
} else if (r.reg == Register::BANK_0::FIFO_CONFIG3) {
// FIFO_WM[11:8] FIFO_CONFIG3
r.set_bits = (fifo_watermark_threshold >> 8) & 0x0F;
}
}
}
void ICM42688P::SelectRegisterBank(enum REG_BANK_SEL_BIT bank, bool force)
{
if (bank != _last_register_bank || force) {
// select BANK_0
uint8_t cmd_bank_sel[2] {};
cmd_bank_sel[0] = static_cast<uint8_t>(Register::BANK_0::REG_BANK_SEL);
cmd_bank_sel[1] = bank;
transfer(cmd_bank_sel, cmd_bank_sel, sizeof(cmd_bank_sel));
_last_register_bank = bank;
}
}
bool ICM42688P::Configure()
{
// first set and clear all configured register bits
for (const auto &reg_cfg : _register_bank0_cfg) {
RegisterSetAndClearBits(reg_cfg.reg, reg_cfg.set_bits, reg_cfg.clear_bits);
}
for (const auto &reg_cfg : _register_bank1_cfg) {
RegisterSetAndClearBits(reg_cfg.reg, reg_cfg.set_bits, reg_cfg.clear_bits);
}
for (const auto &reg_cfg : _register_bank2_cfg) {
RegisterSetAndClearBits(reg_cfg.reg, reg_cfg.set_bits, reg_cfg.clear_bits);
}
// now check that all are configured
bool success = true;
for (const auto &reg_cfg : _register_bank0_cfg) {
if (!RegisterCheck(reg_cfg)) {
success = false;
}
}
for (const auto &reg_cfg : _register_bank1_cfg) {
if (!RegisterCheck(reg_cfg)) {
success = false;
}
}
for (const auto &reg_cfg : _register_bank2_cfg) {
if (!RegisterCheck(reg_cfg)) {
success = false;
}
}
// // 20-bits data format used
// // the only FSR settings that are operational are ±2000dps for gyroscope and ±16g for accelerometer
if (!hitl_mode) {
_px4_accel.set_range(16.f * CONSTANTS_ONE_G);
_px4_accel.set_scale(CONSTANTS_ONE_G / 8192.f);
_px4_gyro.set_range(math::radians(2000.f));
_px4_gyro.set_scale(math::radians(1.f / 131.f));
}
return success;
}
static bool interrupt_debug = true;
static uint32_t interrupt_debug_count = 0;
static const uint32_t interrupt_debug_trigger = 800;
static hrt_abstime last_interrupt_time = 0;
static hrt_abstime avg_interrupt_delta = 0;
static hrt_abstime max_interrupt_delta = 0;
static hrt_abstime min_interrupt_delta = 60 * 1000 * 1000;
static hrt_abstime cumulative_interrupt_delta = 0;
int ICM42688P::DataReadyInterruptCallback(int irq, void *context, void *arg)
{
hrt_abstime current_interrupt_time = hrt_absolute_time();
if (interrupt_debug) {
if (last_interrupt_time) {
hrt_abstime interrupt_delta_time = current_interrupt_time - last_interrupt_time;
if (interrupt_delta_time > max_interrupt_delta) { max_interrupt_delta = interrupt_delta_time; }
if (interrupt_delta_time < min_interrupt_delta) { min_interrupt_delta = interrupt_delta_time; }
cumulative_interrupt_delta += interrupt_delta_time;
}
last_interrupt_time = current_interrupt_time;
interrupt_debug_count++;
if (interrupt_debug_count == interrupt_debug_trigger) {
avg_interrupt_delta = cumulative_interrupt_delta / interrupt_debug_trigger;
PX4_INFO(">>> Max: %llu, Min: %llu, Avg: %llu", max_interrupt_delta,
min_interrupt_delta, avg_interrupt_delta);
interrupt_debug_count = 0;
cumulative_interrupt_delta = 0;
}
}
static_cast<ICM42688P *>(arg)->DataReady();
return 0;
}
void ICM42688P::DataReady()
{
#ifndef __PX4_QURT
uint32_t expected = 0;
if (_drdy_fifo_read_samples.compare_exchange(&expected, _fifo_gyro_samples)) {
ScheduleNow();
}
#else
uint16_t fifo_byte_count = FIFOReadCount();
FIFORead(hrt_absolute_time(), fifo_byte_count / sizeof(FIFO::DATA));
#endif
}
bool ICM42688P::DataReadyInterruptConfigure()
{
if (_drdy_gpio == 0) {
return false;
}
// Setup data ready on falling edge
return px4_arch_gpiosetevent(_drdy_gpio, false, true, true, &DataReadyInterruptCallback, this) == 0;
}
bool ICM42688P::DataReadyInterruptDisable()
{
if (_drdy_gpio == 0) {
return false;
}
return px4_arch_gpiosetevent(_drdy_gpio, false, false, false, nullptr, nullptr) == 0;
}
template <typename T>
bool ICM42688P::RegisterCheck(const T &reg_cfg)
{
bool success = true;
const uint8_t reg_value = RegisterRead(reg_cfg.reg);
if (reg_cfg.set_bits && ((reg_value & reg_cfg.set_bits) != reg_cfg.set_bits)) {
PX4_DEBUG("0x%02hhX: 0x%02hhX (0x%02hhX not set)", (uint8_t)reg_cfg.reg, reg_value, reg_cfg.set_bits);
success = false;
}
if (reg_cfg.clear_bits && ((reg_value & reg_cfg.clear_bits) != 0)) {
PX4_DEBUG("0x%02hhX: 0x%02hhX (0x%02hhX not cleared)", (uint8_t)reg_cfg.reg, reg_value, reg_cfg.clear_bits);
success = false;
}
return success;
}
template <typename T>
uint8_t ICM42688P::RegisterRead(T reg)
{
uint8_t cmd[2] {};
cmd[0] = static_cast<uint8_t>(reg) | DIR_READ;
SelectRegisterBank(reg);
transfer(cmd, cmd, sizeof(cmd));
return cmd[1];
}
template <typename T>
void ICM42688P::RegisterWrite(T reg, uint8_t value)
{
uint8_t cmd[2] { (uint8_t)reg, value };
SelectRegisterBank(reg);
transfer(cmd, cmd, sizeof(cmd));
}
template <typename T>
void ICM42688P::RegisterSetAndClearBits(T reg, uint8_t setbits, uint8_t clearbits)
{
const uint8_t orig_val = RegisterRead(reg);
uint8_t val = (orig_val & ~clearbits) | setbits;
if (orig_val != val) {
RegisterWrite(reg, val);
}
}
uint16_t ICM42688P::FIFOReadCount()
{
// read FIFO count
uint8_t fifo_count_buf[3] {};
fifo_count_buf[0] = static_cast<uint8_t>(Register::BANK_0::FIFO_COUNTH) | DIR_READ;
SelectRegisterBank(REG_BANK_SEL_BIT::USER_BANK_0);
if (transfer(fifo_count_buf, fifo_count_buf, sizeof(fifo_count_buf)) != PX4_OK) {
perf_count(_bad_transfer_perf);
return 0;
}
return combine(fifo_count_buf[1], fifo_count_buf[2]);
}
// static uint32_t debug_decimator = 0;
// static hrt_abstime last_sample_time = 0;
// static bool imu_debug = true;
bool ICM42688P::FIFORead(const hrt_abstime &timestamp_sample, uint16_t samples)
{
FIFOTransferBuffer buffer{};
const size_t max_transfer_size = 10 * sizeof(FIFO::DATA) + 4;
const size_t transfer_size = math::min(samples * sizeof(FIFO::DATA) + 4, max_transfer_size);
SelectRegisterBank(REG_BANK_SEL_BIT::USER_BANK_0);
if (transfer((uint8_t *)&buffer, (uint8_t *)&buffer, transfer_size) != PX4_OK) {
perf_count(_bad_transfer_perf);
return false;
}
if (buffer.INT_STATUS & INT_STATUS_BIT::FIFO_FULL_INT) {
perf_count(_fifo_overflow_perf);
FIFOReset();
return false;
}
const uint16_t fifo_count_bytes = combine(buffer.FIFO_COUNTH, buffer.FIFO_COUNTL);
if (fifo_count_bytes >= FIFO::SIZE) {
perf_count(_fifo_overflow_perf);
FIFOReset();
return false;
}
const uint16_t fifo_count_samples = fifo_count_bytes / sizeof(FIFO::DATA);
if (fifo_count_samples == 0) {
perf_count(_fifo_empty_perf);
return false;
}
// check FIFO header in every sample
uint16_t valid_samples = 0;
// for (int i = 0; i < math::min(samples, fifo_count_samples); i++) {
for (int i = 0; i < math::min(samples, (uint16_t) 10); i++) {
bool valid = true;
// With FIFO_ACCEL_EN and FIFO_GYRO_EN header should be 8b_0110_10xx
const uint8_t FIFO_HEADER = buffer.f[i].FIFO_Header;
if (FIFO_HEADER & FIFO::FIFO_HEADER_BIT::HEADER_MSG) {
// FIFO sample empty if HEADER_MSG set
valid = false;
} else if (!(FIFO_HEADER & FIFO::FIFO_HEADER_BIT::HEADER_ACCEL)) {
// accel bit not set
valid = false;
} else if (!(FIFO_HEADER & FIFO::FIFO_HEADER_BIT::HEADER_GYRO)) {
// gyro bit not set
valid = false;
} else if (!(FIFO_HEADER & FIFO::FIFO_HEADER_BIT::HEADER_20)) {
// Packet does not contain a new and valid extended 20-bit data
valid = false;
} else if (FIFO_HEADER & FIFO::FIFO_HEADER_BIT::HEADER_ODR_ACCEL) {
// accel ODR changed
valid = false;
} else if (FIFO_HEADER & FIFO::FIFO_HEADER_BIT::HEADER_ODR_GYRO) {
// gyro ODR changed
valid = false;
}
if (valid) {
valid_samples++;
} else {
perf_count(_bad_transfer_perf);
break;
}
}
// if (imu_debug) {
// debug_decimator++;
// if (debug_decimator == 801) {
// debug_decimator = 0;
// PX4_INFO("Initial: %u Next: %u Valid: %u Delta: %llu", samples, fifo_count_samples, valid_samples, timestamp_sample - last_sample_time);
// }
// last_sample_time = timestamp_sample;
// }
if (valid_samples > 0) {
if (ProcessTemperature(buffer.f, valid_samples)) {
ProcessGyro(timestamp_sample, buffer.f, valid_samples);
ProcessAccel(timestamp_sample, buffer.f, valid_samples);
// Pass only most recent valid sample to IMU server
// ProcessIMU(timestamp_sample, buffer.f[valid_samples - 1]);
return true;
}
}
return false;
}
void ICM42688P::FIFOReset()
{
perf_count(_fifo_reset_perf);
// SIGNAL_PATH_RESET: FIFO flush
RegisterSetBits(Register::BANK_0::SIGNAL_PATH_RESET, SIGNAL_PATH_RESET_BIT::FIFO_FLUSH);
// reset while FIFO is disabled
_drdy_fifo_read_samples.store(0);
}
static constexpr int32_t reassemble_20bit(const uint32_t a, const uint32_t b, const uint32_t c)
{
// 0xXXXAABBC
uint32_t high = ((a << 12) & 0x000FF000);
uint32_t low = ((b << 4) & 0x00000FF0);
uint32_t lowest = (c & 0x0000000F);
uint32_t x = high | low | lowest;
if (a & Bit7) {
// sign extend
x |= 0xFFF00000u;
}
return static_cast<int32_t>(x);
}
void ICM42688P::ProcessIMU(const hrt_abstime &timestamp_sample, const FIFO::DATA &fifo)
{
// float accel_x = 0.0, accel_y = 0.0, accel_z = 0.0;
// float gyro_x = 0.0, gyro_y = 0.0, gyro_z = 0.0;
//
// // 20 bit hires mode
//
// // Sign extension + Accel [19:12] + Accel [11:4] + Accel [3:2] (20 bit extension byte)
// // Accel data is 18 bit
// int32_t temp_accel_x = reassemble_20bit(fifo.ACCEL_DATA_X1, fifo.ACCEL_DATA_X0,
// fifo.Ext_Accel_X_Gyro_X & 0xF0 >> 4);
// int32_t temp_accel_y = reassemble_20bit(fifo.ACCEL_DATA_Y1, fifo.ACCEL_DATA_Y0,
// fifo.Ext_Accel_Y_Gyro_Y & 0xF0 >> 4);
// int32_t temp_accel_z = reassemble_20bit(fifo.ACCEL_DATA_Z1, fifo.ACCEL_DATA_Z0,
// fifo.Ext_Accel_Z_Gyro_Z & 0xF0 >> 4);
//
// // Gyro [19:12] + Gyro [11:4] + Gyro [3:0] (bottom 4 bits of 20 bit extension byte)
// int32_t temp_gyro_x = reassemble_20bit(fifo.GYRO_DATA_X1, fifo.GYRO_DATA_X0,
// fifo.Ext_Accel_X_Gyro_X & 0x0F);
// int32_t temp_gyro_y = reassemble_20bit(fifo.GYRO_DATA_Y1, fifo.GYRO_DATA_Y0,
// fifo.Ext_Accel_Y_Gyro_Y & 0x0F);
// int32_t temp_gyro_z = reassemble_20bit(fifo.GYRO_DATA_Z1, fifo.GYRO_DATA_Z0,
// fifo.Ext_Accel_Z_Gyro_Z & 0x0F);
// // accel samples invalid if -524288
// if (temp_accel_x != -524288 && temp_accel_y != -524288 && temp_accel_z != -524288) {
// // shift accel by 2 (2 least significant bits are always 0)
// accel_x = (float) temp_accel_x / 4.f;
// accel_y = (float) temp_accel_y / 4.f;
// accel_z = (float) temp_accel_z / 4.f;
//
// // shift gyro by 1 (least significant bit is always 0)
// gyro_x = (float) temp_gyro_x / 2.f;
// gyro_y = (float) temp_gyro_y / 2.f;
// gyro_z = (float) temp_gyro_z / 2.f;
//
// // correct frame for publication
// // sensor's frame is +x forward, +y left, +z up
// // flip y & z to publish right handed with z down (x forward, y right, z down)
// accel_y = -accel_y;
// accel_z = -accel_z;
// gyro_y = -gyro_y;
// gyro_z = -gyro_z;
//
// // Scale everything appropriately
// float accel_scale_factor = (CONSTANTS_ONE_G / 8192.f);
// accel_x *= accel_scale_factor;
// accel_y *= accel_scale_factor;
// accel_z *= accel_scale_factor;
//
// float gyro_scale_factor = math::radians(1.f / 131.f);
// gyro_x *= gyro_scale_factor;
// gyro_y *= gyro_scale_factor;
// gyro_z *= gyro_scale_factor;
//
// // Store the data in our array
// _imu_server_data.accel_x[_imu_server_index] = accel_x;
// _imu_server_data.accel_y[_imu_server_index] = accel_y;
// _imu_server_data.accel_z[_imu_server_index] = accel_z;
// _imu_server_data.gyro_x[_imu_server_index] = gyro_x;
// _imu_server_data.gyro_y[_imu_server_index] = gyro_y;
// _imu_server_data.gyro_z[_imu_server_index] = gyro_z;
// _imu_server_data.ts[_imu_server_index] = timestamp_sample;
// _imu_server_index++;
//
// // If array is full, publish the data
// if (_imu_server_index == 10) {
// _imu_server_index = 0;
// _imu_server_data.timestamp = hrt_absolute_time();
// _imu_server_data.temperature = 0; // Not used right now
// _imu_server_pub.publish(_imu_server_data);
// }
// }
}
void ICM42688P::ProcessAccel(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples)
{
sensor_accel_fifo_s accel{};
accel.timestamp_sample = timestamp_sample;
accel.samples = 0;
accel.dt = FIFO_SAMPLE_DT;
// 18-bits of accelerometer data
bool scale_20bit = false;
// first pass
for (int i = 0; i < samples; i++) {
// 20 bit hires mode
// Sign extension + Accel [19:12] + Accel [11:4] + Accel [3:2] (20 bit extension byte)
// Accel data is 18 bit ()
int32_t accel_x = reassemble_20bit(fifo[i].ACCEL_DATA_X1, fifo[i].ACCEL_DATA_X0,
fifo[i].Ext_Accel_X_Gyro_X & 0xF0 >> 4);
int32_t accel_y = reassemble_20bit(fifo[i].ACCEL_DATA_Y1, fifo[i].ACCEL_DATA_Y0,
fifo[i].Ext_Accel_Y_Gyro_Y & 0xF0 >> 4);
int32_t accel_z = reassemble_20bit(fifo[i].ACCEL_DATA_Z1, fifo[i].ACCEL_DATA_Z0,
fifo[i].Ext_Accel_Z_Gyro_Z & 0xF0 >> 4);
// sample invalid if -524288
if (accel_x != -524288 && accel_y != -524288 && accel_z != -524288) {
// check if any values are going to exceed int16 limits
static constexpr int16_t max_accel = INT16_MAX;
static constexpr int16_t min_accel = INT16_MIN;
if (accel_x >= max_accel || accel_x <= min_accel) {
scale_20bit = true;
}
if (accel_y >= max_accel || accel_y <= min_accel) {
scale_20bit = true;
}
if (accel_z >= max_accel || accel_z <= min_accel) {
scale_20bit = true;
}
// shift by 2 (2 least significant bits are always 0)
accel.x[accel.samples] = accel_x / 4;
accel.y[accel.samples] = accel_y / 4;
accel.z[accel.samples] = accel_z / 4;
accel.samples++;
}
}
if (!scale_20bit) {
// if highres enabled accel data is always 8192 LSB/g
if (!hitl_mode) {
_px4_accel.set_scale(CONSTANTS_ONE_G / 8192.f);
}
} else {
// 20 bit data scaled to 16 bit (2^4)
for (int i = 0; i < samples; i++) {
// 20 bit hires mode
// Sign extension + Accel [19:12] + Accel [11:4] + Accel [3:2] (20 bit extension byte)
// Accel data is 18 bit ()
int16_t accel_x = combine(fifo[i].ACCEL_DATA_X1, fifo[i].ACCEL_DATA_X0);
int16_t accel_y = combine(fifo[i].ACCEL_DATA_Y1, fifo[i].ACCEL_DATA_Y0);
int16_t accel_z = combine(fifo[i].ACCEL_DATA_Z1, fifo[i].ACCEL_DATA_Z0);
accel.x[i] = accel_x;
accel.y[i] = accel_y;
accel.z[i] = accel_z;
}
if (!hitl_mode) {
_px4_accel.set_scale(CONSTANTS_ONE_G / 2048.f);
}
}
// correct frame for publication
for (int i = 0; i < accel.samples; i++) {
// sensor's frame is +x forward, +y left, +z up
// flip y & z to publish right handed with z down (x forward, y right, z down)
accel.x[i] = accel.x[i];
accel.y[i] = (accel.y[i] == INT16_MIN) ? INT16_MAX : -accel.y[i];
accel.z[i] = (accel.z[i] == INT16_MIN) ? INT16_MAX : -accel.z[i];
}
if (!hitl_mode) {
_px4_accel.set_error_count(perf_event_count(_bad_register_perf) + perf_event_count(_bad_transfer_perf) +
perf_event_count(_fifo_empty_perf) + perf_event_count(_fifo_overflow_perf));
}
if (accel.samples > 0) {
if (!hitl_mode) {
_px4_accel.updateFIFO(accel);
}
}
}
void ICM42688P::ProcessGyro(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples)
{
sensor_gyro_fifo_s gyro{};
gyro.timestamp_sample = timestamp_sample;
gyro.samples = 0;
gyro.dt = FIFO_SAMPLE_DT;
// 20-bits of gyroscope data
bool scale_20bit = false;
// first pass
for (int i = 0; i < samples; i++) {
// 20 bit hires mode
// Gyro [19:12] + Gyro [11:4] + Gyro [3:0] (bottom 4 bits of 20 bit extension byte)
int32_t gyro_x = reassemble_20bit(fifo[i].GYRO_DATA_X1, fifo[i].GYRO_DATA_X0, fifo[i].Ext_Accel_X_Gyro_X & 0x0F);
int32_t gyro_y = reassemble_20bit(fifo[i].GYRO_DATA_Y1, fifo[i].GYRO_DATA_Y0, fifo[i].Ext_Accel_Y_Gyro_Y & 0x0F);
int32_t gyro_z = reassemble_20bit(fifo[i].GYRO_DATA_Z1, fifo[i].GYRO_DATA_Z0, fifo[i].Ext_Accel_Z_Gyro_Z & 0x0F);
// check if any values are going to exceed int16 limits
static constexpr int16_t max_gyro = INT16_MAX;
static constexpr int16_t min_gyro = INT16_MIN;
if (gyro_x >= max_gyro || gyro_x <= min_gyro) {
scale_20bit = true;
}
if (gyro_y >= max_gyro || gyro_y <= min_gyro) {
scale_20bit = true;
}
if (gyro_z >= max_gyro || gyro_z <= min_gyro) {
scale_20bit = true;
}
gyro.x[gyro.samples] = gyro_x / 2;
gyro.y[gyro.samples] = gyro_y / 2;
gyro.z[gyro.samples] = gyro_z / 2;
gyro.samples++;
}
if (!scale_20bit) {
// if highres enabled gyro data is always 131 LSB/dps
if (!hitl_mode) {
_px4_gyro.set_scale(math::radians(1.f / 131.f));
}
} else {
// 20 bit data scaled to 16 bit (2^4)
for (int i = 0; i < samples; i++) {
gyro.x[i] = combine(fifo[i].GYRO_DATA_X1, fifo[i].GYRO_DATA_X0);
gyro.y[i] = combine(fifo[i].GYRO_DATA_Y1, fifo[i].GYRO_DATA_Y0);
gyro.z[i] = combine(fifo[i].GYRO_DATA_Z1, fifo[i].GYRO_DATA_Z0);
}
if (!hitl_mode) {
_px4_gyro.set_scale(math::radians(2000.f / 32768.f));
}
}
// correct frame for publication
for (int i = 0; i < gyro.samples; i++) {
// sensor's frame is +x forward, +y left, +z up
// flip y & z to publish right handed with z down (x forward, y right, z down)
gyro.x[i] = gyro.x[i];
gyro.y[i] = (gyro.y[i] == INT16_MIN) ? INT16_MAX : -gyro.y[i];
gyro.z[i] = (gyro.z[i] == INT16_MIN) ? INT16_MAX : -gyro.z[i];
}
if (!hitl_mode) {
_px4_gyro.set_error_count(perf_event_count(_bad_register_perf) + perf_event_count(_bad_transfer_perf) +
perf_event_count(_fifo_empty_perf) + perf_event_count(_fifo_overflow_perf));
}
if (gyro.samples > 0) {
if (!hitl_mode) {
_px4_gyro.updateFIFO(gyro);
}
}
}
bool ICM42688P::ProcessTemperature(const FIFO::DATA fifo[], const uint8_t samples)
{
int16_t temperature[FIFO_MAX_SAMPLES];
float temperature_sum{0};
int valid_samples = 0;
for (int i = 0; i < samples; i++) {
const int16_t t = combine(fifo[i].TEMP_DATA1, fifo[i].TEMP_DATA0);
// sample invalid if -32768
if (t != -32768) {
temperature_sum += t;
temperature[valid_samples] = t;
valid_samples++;
}
}
if (valid_samples > 0) {
const float temperature_avg = temperature_sum / valid_samples;
for (int i = 0; i < valid_samples; i++) {
// temperature changing wildly is an indication of a transfer error
if (fabsf(temperature[i] - temperature_avg) > 1000) {
perf_count(_bad_transfer_perf);
return false;
}
}
// use average temperature reading
const float TEMP_degC = (temperature_avg / TEMPERATURE_SENSITIVITY) + TEMPERATURE_OFFSET;
if (PX4_ISFINITE(TEMP_degC)) {
if (!hitl_mode) {
_px4_accel.set_temperature(TEMP_degC);
_px4_gyro.set_temperature(TEMP_degC);
return true;
}
} else {
perf_count(_bad_transfer_perf);
}
}
return false;
}

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/****************************************************************************
*
* Copyright (c) 2020 PX4 Development Team. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
/**
* @file ICM42688P.hpp
*
* Driver for the Invensense ICM42688P connected via SPI.
*
*/
#pragma once
#include "InvenSense_ICM42688P_registers.hpp"
#include <drivers/drv_hrt.h>
#include <lib/drivers/accelerometer/PX4Accelerometer.hpp>
#include <lib/drivers/device/spi.h>
#include <lib/drivers/gyroscope/PX4Gyroscope.hpp>
#include <lib/geo/geo.h>
#include <lib/perf/perf_counter.h>
#include <px4_platform_common/atomic.h>
#include <px4_platform_common/i2c_spi_buses.h>
#include <uORB/topics/sensor_accel_fifo.h>
#include <uORB/topics/sensor_gyro_fifo.h>
#include <memory>
using namespace InvenSense_ICM42688P;
extern bool hitl_mode;
class ICM42688P : public device::SPI, public I2CSPIDriver<ICM42688P>
{
public:
// ICM42688P(I2CSPIBusOption bus_option, int bus, uint32_t device, enum Rotation rotation, int bus_frequency,
// spi_mode_e spi_mode, spi_drdy_gpio_t drdy_gpio);
ICM42688P(const I2CSPIDriverConfig &config);
~ICM42688P() override;
// static I2CSPIDriverBase *instantiate(const BusCLIArguments &cli, const BusInstanceIterator &iterator,
// int runtime_instance);
static void print_usage();
void RunImpl();
int init() override;
void print_status() override;
private:
void exit_and_cleanup() override;
// Sensor Configuration
static constexpr float IMU_ODR{8000.f}; // 8kHz accel & gyro ODR configured
static constexpr float FIFO_SAMPLE_DT{1e6f / IMU_ODR};
static constexpr float GYRO_RATE{1e6f / FIFO_SAMPLE_DT};
static constexpr float ACCEL_RATE{1e6f / FIFO_SAMPLE_DT};
// maximum FIFO samples per transfer is limited to the size of sensor_accel_fifo/sensor_gyro_fifo
// static constexpr uint32_t FIFO_MAX_SAMPLES{math::min(math::min(FIFO::SIZE / sizeof(FIFO::DATA), sizeof(sensor_gyro_fifo_s::x) / sizeof(sensor_gyro_fifo_s::x[0])), sizeof(sensor_accel_fifo_s::x) / sizeof(sensor_accel_fifo_s::x[0]) * (int)(GYRO_RATE / ACCEL_RATE))};
static constexpr uint32_t FIFO_MAX_SAMPLES{10};
// Transfer data
struct FIFOTransferBuffer {
uint8_t cmd{static_cast<uint8_t>(Register::BANK_0::INT_STATUS) | DIR_READ};
uint8_t INT_STATUS{0};
uint8_t FIFO_COUNTH{0};
uint8_t FIFO_COUNTL{0};
FIFO::DATA f[FIFO_MAX_SAMPLES] {};
};
// ensure no struct padding
static_assert(sizeof(FIFOTransferBuffer) == (4 + FIFO_MAX_SAMPLES *sizeof(FIFO::DATA)),
"Invalid FIFOTransferBuffer size");
struct register_bank0_config_t {
Register::BANK_0 reg;
uint8_t set_bits{0};
uint8_t clear_bits{0};
};
struct register_bank1_config_t {
Register::BANK_1 reg;
uint8_t set_bits{0};
uint8_t clear_bits{0};
};
struct register_bank2_config_t {
Register::BANK_2 reg;
uint8_t set_bits{0};
uint8_t clear_bits{0};
};
int probe() override;
bool Reset();
bool Configure();
void ConfigureSampleRate(int sample_rate);
void ConfigureFIFOWatermark(uint8_t samples);
void SelectRegisterBank(enum REG_BANK_SEL_BIT bank, bool force = false);
void SelectRegisterBank(Register::BANK_0 reg) { SelectRegisterBank(REG_BANK_SEL_BIT::USER_BANK_0); }
void SelectRegisterBank(Register::BANK_1 reg) { SelectRegisterBank(REG_BANK_SEL_BIT::USER_BANK_1); }
void SelectRegisterBank(Register::BANK_2 reg) { SelectRegisterBank(REG_BANK_SEL_BIT::USER_BANK_2); }
static int DataReadyInterruptCallback(int irq, void *context, void *arg);
void DataReady();
bool DataReadyInterruptConfigure();
bool DataReadyInterruptDisable();
template <typename T> bool RegisterCheck(const T &reg_cfg);
template <typename T> uint8_t RegisterRead(T reg);
template <typename T> void RegisterWrite(T reg, uint8_t value);
template <typename T> void RegisterSetAndClearBits(T reg, uint8_t setbits, uint8_t clearbits);
template <typename T> void RegisterSetBits(T reg, uint8_t setbits) { RegisterSetAndClearBits(reg, setbits, 0); }
template <typename T> void RegisterClearBits(T reg, uint8_t clearbits) { RegisterSetAndClearBits(reg, 0, clearbits); }
uint16_t FIFOReadCount();
bool FIFORead(const hrt_abstime &timestamp_sample, uint16_t samples);
void FIFOReset();
void ProcessIMU(const hrt_abstime &timestamp_sample, const FIFO::DATA &fifo);
void ProcessAccel(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples);
void ProcessGyro(const hrt_abstime &timestamp_sample, const FIFO::DATA fifo[], const uint8_t samples);
bool ProcessTemperature(const FIFO::DATA fifo[], const uint8_t samples);
const spi_drdy_gpio_t _drdy_gpio;
// std::shared_ptr<PX4Accelerometer> _px4_accel;
// std::shared_ptr<PX4Gyroscope> _px4_gyro;
PX4Accelerometer _px4_accel;
PX4Gyroscope _px4_gyro;
perf_counter_t _bad_register_perf{perf_alloc(PC_COUNT, MODULE_NAME": bad register")};
perf_counter_t _bad_transfer_perf{perf_alloc(PC_COUNT, MODULE_NAME": bad transfer")};
perf_counter_t _fifo_empty_perf{perf_alloc(PC_COUNT, MODULE_NAME": FIFO empty")};
perf_counter_t _fifo_overflow_perf{perf_alloc(PC_COUNT, MODULE_NAME": FIFO overflow")};
perf_counter_t _fifo_reset_perf{perf_alloc(PC_COUNT, MODULE_NAME": FIFO reset")};
perf_counter_t _drdy_missed_perf{nullptr};
hrt_abstime _reset_timestamp{0};
hrt_abstime _last_config_check_timestamp{0};
hrt_abstime _temperature_update_timestamp{0};
int _failure_count{0};
enum REG_BANK_SEL_BIT _last_register_bank {REG_BANK_SEL_BIT::USER_BANK_0};
px4::atomic<uint32_t> _drdy_fifo_read_samples{0};
bool _data_ready_interrupt_enabled{false};
enum class STATE : uint8_t {
RESET,
WAIT_FOR_RESET,
CONFIGURE,
FIFO_READ,
} _state{STATE::RESET};
uint16_t _fifo_empty_interval_us{1250}; // default 1250 us / 800 Hz transfer interval
uint32_t _fifo_gyro_samples{static_cast<uint32_t>(_fifo_empty_interval_us / (1000000 / GYRO_RATE))};
uint8_t _checked_register_bank0{0};
static constexpr uint8_t size_register_bank0_cfg{12};
register_bank0_config_t _register_bank0_cfg[size_register_bank0_cfg] {
// Register | Set bits, Clear bits
{ Register::BANK_0::INT_CONFIG, INT_CONFIG_BIT::INT1_MODE | INT_CONFIG_BIT::INT1_DRIVE_CIRCUIT, INT_CONFIG_BIT::INT1_POLARITY },
{ Register::BANK_0::FIFO_CONFIG, FIFO_CONFIG_BIT::FIFO_MODE_STOP_ON_FULL, 0 },
{ Register::BANK_0::GYRO_CONFIG0, GYRO_CONFIG0_BIT::GYRO_FS_SEL_2000_DPS | GYRO_CONFIG0_BIT::GYRO_ODR_8KHZ_SET, GYRO_CONFIG0_BIT::GYRO_ODR_8KHZ_CLEAR },
{ Register::BANK_0::ACCEL_CONFIG0, ACCEL_CONFIG0_BIT::ACCEL_FS_SEL_16G | ACCEL_CONFIG0_BIT::ACCEL_ODR_8KHZ_SET, ACCEL_CONFIG0_BIT::ACCEL_ODR_8KHZ_CLEAR },
{ Register::BANK_0::GYRO_CONFIG1, 0, GYRO_CONFIG1_BIT::GYRO_UI_FILT_ORD },
{ Register::BANK_0::GYRO_ACCEL_CONFIG0, 0, GYRO_ACCEL_CONFIG0_BIT::ACCEL_UI_FILT_BW | GYRO_ACCEL_CONFIG0_BIT::GYRO_UI_FILT_BW },
{ Register::BANK_0::ACCEL_CONFIG1, 0, ACCEL_CONFIG1_BIT::ACCEL_UI_FILT_ORD },
{ Register::BANK_0::FIFO_CONFIG1, FIFO_CONFIG1_BIT::FIFO_WM_GT_TH | FIFO_CONFIG1_BIT::FIFO_HIRES_EN | FIFO_CONFIG1_BIT::FIFO_TEMP_EN | FIFO_CONFIG1_BIT::FIFO_GYRO_EN | FIFO_CONFIG1_BIT::FIFO_ACCEL_EN, 0 },
{ Register::BANK_0::FIFO_CONFIG2, 0, 0 }, // FIFO_WM[7:0] set at runtime
{ Register::BANK_0::FIFO_CONFIG3, 0, 0 }, // FIFO_WM[11:8] set at runtime
{ Register::BANK_0::INT_CONFIG0, INT_CONFIG0_BIT::CLEAR_ON_FIFO_READ, 0 },
{ Register::BANK_0::INT_SOURCE0, INT_SOURCE0_BIT::FIFO_THS_INT1_EN, 0 },
};
uint8_t _checked_register_bank1{0};
static constexpr uint8_t size_register_bank1_cfg{4};
register_bank1_config_t _register_bank1_cfg[size_register_bank1_cfg] {
// Register | Set bits, Clear bits
{ Register::BANK_1::GYRO_CONFIG_STATIC2, 0, GYRO_CONFIG_STATIC2_BIT::GYRO_NF_DIS | GYRO_CONFIG_STATIC2_BIT::GYRO_AAF_DIS },
{ Register::BANK_1::GYRO_CONFIG_STATIC3, GYRO_CONFIG_STATIC3_BIT::GYRO_AAF_DELT_SET, GYRO_CONFIG_STATIC3_BIT::GYRO_AAF_DELT_CLEAR},
{ Register::BANK_1::GYRO_CONFIG_STATIC4, GYRO_CONFIG_STATIC4_BIT::GYRO_AAF_DELTSQR_LOW_SET, GYRO_CONFIG_STATIC4_BIT::GYRO_AAF_DELTSQR_LOW_CLEAR},
{ Register::BANK_1::GYRO_CONFIG_STATIC5, GYRO_CONFIG_STATIC5_BIT::GYRO_AAF_BITSHIFT_SET | GYRO_CONFIG_STATIC5_BIT::GYRO_AAF_DELTSQR_HIGH_SET, GYRO_CONFIG_STATIC5_BIT::GYRO_AAF_BITSHIFT_CLEAR | GYRO_CONFIG_STATIC5_BIT::GYRO_AAF_DELTSQR_HIGH_CLEAR},
};
uint8_t _checked_register_bank2{0};
static constexpr uint8_t size_register_bank2_cfg{3};
register_bank2_config_t _register_bank2_cfg[size_register_bank2_cfg] {
// Register | Set bits, Clear bits
{ Register::BANK_2::ACCEL_CONFIG_STATIC2, ACCEL_CONFIG_STATIC2_BIT::ACCEL_AAF_DELT_SET, ACCEL_CONFIG_STATIC2_BIT::ACCEL_AAF_DELT_CLEAR | ACCEL_CONFIG_STATIC2_BIT::ACCEL_AAF_DIS },
{ Register::BANK_2::ACCEL_CONFIG_STATIC3, ACCEL_CONFIG_STATIC3_BIT::ACCEL_AAF_DELTSQR_LOW_SET, ACCEL_CONFIG_STATIC3_BIT::ACCEL_AAF_DELTSQR_LOW_CLEAR },
{ Register::BANK_2::ACCEL_CONFIG_STATIC4, ACCEL_CONFIG_STATIC4_BIT::ACCEL_AAF_BITSHIFT_SET | ACCEL_CONFIG_STATIC4_BIT::ACCEL_AAF_DELTSQR_HIGH_SET, ACCEL_CONFIG_STATIC4_BIT::ACCEL_AAF_BITSHIFT_CLEAR | ACCEL_CONFIG_STATIC4_BIT::ACCEL_AAF_DELTSQR_HIGH_CLEAR },
};
uint32_t _temperature_samples{0};
// Support for the IMU server
// uint32_t _imu_server_index{0};
// imu_server_s _imu_server_data;
// uORB::Publication<imu_server_s> _imu_server_pub{ORB_ID(imu_server)};
};

430
boards/modalai/voxl2-slpi/src/drivers/icm42688p/InvenSense_ICM42688P_registers.hpp Normal file
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@ -0,0 +1,430 @@
/****************************************************************************
*
* Copyright (c) 2020 PX4 Development Team. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
/**
* @file InvenSense_ICM42688P_registers.hpp
*
* Invensense ICM-42688-P registers.
*
*/
#pragma once
#include <cstdint>
namespace InvenSense_ICM42688P
{
// TODO: move to a central header
static constexpr uint8_t Bit0 = (1 << 0);
static constexpr uint8_t Bit1 = (1 << 1);
static constexpr uint8_t Bit2 = (1 << 2);
static constexpr uint8_t Bit3 = (1 << 3);
static constexpr uint8_t Bit4 = (1 << 4);
static constexpr uint8_t Bit5 = (1 << 5);
static constexpr uint8_t Bit6 = (1 << 6);
static constexpr uint8_t Bit7 = (1 << 7);
static constexpr uint32_t SPI_SPEED = 24 * 1000 * 1000; // 24 MHz SPI
static constexpr uint8_t DIR_READ = 0x80;
static constexpr uint8_t WHOAMI = 0x47;
static constexpr float TEMPERATURE_SENSITIVITY = 132.48f; // LSB/C
static constexpr float TEMPERATURE_OFFSET = 25.f; // C
namespace Register
{
enum class BANK_0 : uint8_t {
DEVICE_CONFIG = 0x11,
INT_CONFIG = 0x14,
FIFO_CONFIG = 0x16,
TEMP_DATA1 = 0x1D,
TEMP_DATA0 = 0x1E,
INT_STATUS = 0x2D,
FIFO_COUNTH = 0x2E,
FIFO_COUNTL = 0x2F,
FIFO_DATA = 0x30,
SIGNAL_PATH_RESET = 0x4B,
INTF_CONFIG0 = 0x4C,
INTF_CONFIG1 = 0x4D,
PWR_MGMT0 = 0x4E,
GYRO_CONFIG0 = 0x4F,
ACCEL_CONFIG0 = 0x50,
GYRO_CONFIG1 = 0x51,
GYRO_ACCEL_CONFIG0 = 0x52,
ACCEL_CONFIG1 = 0x53,
FIFO_CONFIG1 = 0x5F,
FIFO_CONFIG2 = 0x60,
FIFO_CONFIG3 = 0x61,
INT_CONFIG0 = 0x63,
INT_SOURCE0 = 0x65,
SELF_TEST_CONFIG = 0x70,
WHO_AM_I = 0x75,
REG_BANK_SEL = 0x76,
};
enum class BANK_1 : uint8_t {
GYRO_CONFIG_STATIC2 = 0x0B,
GYRO_CONFIG_STATIC3 = 0x0C,
GYRO_CONFIG_STATIC4 = 0x0D,
GYRO_CONFIG_STATIC5 = 0x0E,
INTF_CONFIG5 = 0x7B,
};
enum class BANK_2 : uint8_t {
ACCEL_CONFIG_STATIC2 = 0x03,
ACCEL_CONFIG_STATIC3 = 0x04,
ACCEL_CONFIG_STATIC4 = 0x05,
};
};
//---------------- BANK0 Register bits
// DEVICE_CONFIG
enum DEVICE_CONFIG_BIT : uint8_t {
SOFT_RESET_CONFIG = Bit0, //
};
// INT_CONFIG
enum INT_CONFIG_BIT : uint8_t {
INT1_MODE = Bit2,
INT1_DRIVE_CIRCUIT = Bit1,
INT1_POLARITY = Bit0,
};
// FIFO_CONFIG
enum FIFO_CONFIG_BIT : uint8_t {
// 7:6 FIFO_MODE
FIFO_MODE_STOP_ON_FULL = Bit7 | Bit6, // 11: STOP-on-FULL Mode
};
// INT_STATUS
enum INT_STATUS_BIT : uint8_t {
RESET_DONE_INT = Bit4,
DATA_RDY_INT = Bit3,
FIFO_THS_INT = Bit2,
FIFO_FULL_INT = Bit1,
};
// SIGNAL_PATH_RESET
enum SIGNAL_PATH_RESET_BIT : uint8_t {
ABORT_AND_RESET = Bit3,
FIFO_FLUSH = Bit1,
};
// PWR_MGMT0
enum PWR_MGMT0_BIT : uint8_t {
GYRO_MODE_LOW_NOISE = Bit3 | Bit2, // 11: Places gyroscope in Low Noise (LN) Mode
ACCEL_MODE_LOW_NOISE = Bit1 | Bit0, // 11: Places accelerometer in Low Noise (LN) Mode
};
// GYRO_CONFIG0
enum GYRO_CONFIG0_BIT : uint8_t {
// 7:5 GYRO_FS_SEL
GYRO_FS_SEL_2000_DPS = 0, // 0b000 = ±2000dps (default)
GYRO_FS_SEL_1000_DPS = Bit5,
GYRO_FS_SEL_500_DPS = Bit6,
GYRO_FS_SEL_250_DPS = Bit6 | Bit5,
GYRO_FS_SEL_125_DPS = Bit7,
// 3:0 GYRO_ODR
// 0001: 32kHz
GYRO_ODR_32KHZ_SET = Bit0,
GYRO_ODR_32KHZ_CLEAR = Bit3 | Bit2 | Bit0,
// 0010: 16kHz
GYRO_ODR_16KHZ_SET = Bit1,
GYRO_ODR_16KHZ_CLEAR = Bit3 | Bit2 | Bit0,
// 0011: 8kHz
GYRO_ODR_8KHZ_SET = Bit1 | Bit0,
GYRO_ODR_8KHZ_CLEAR = Bit3 | Bit2,
// 0110: 1kHz (default)
GYRO_ODR_1KHZ_SET = Bit2 | Bit1,
GYRO_ODR_1KHZ_CLEAR = Bit3 | Bit0,
};
// ACCEL_CONFIG0
enum ACCEL_CONFIG0_BIT : uint8_t {
// 7:5 ACCEL_FS_SEL
ACCEL_FS_SEL_16G = 0, // 000: ±16g (default)
ACCEL_FS_SEL_8G = Bit5,
ACCEL_FS_SEL_4G = Bit6,
ACCEL_FS_SEL_2G = Bit6 | Bit5,
// 3:0 ACCEL_ODR
// 0001: 32kHz
ACCEL_ODR_32KHZ_SET = Bit0,
ACCEL_ODR_32KHZ_CLEAR = Bit3 | Bit2 | Bit0,
// 0010: 16kHz
ACCEL_ODR_16KHZ_SET = Bit1,
ACCEL_ODR_16KHZ_CLEAR = Bit3 | Bit2 | Bit0,
// 0011: 8kHz
ACCEL_ODR_8KHZ_SET = Bit1 | Bit0,
ACCEL_ODR_8KHZ_CLEAR = Bit3 | Bit2,
// 0110: 1kHz (default)
ACCEL_ODR_1KHZ_SET = Bit2 | Bit1,
ACCEL_ODR_1KHZ_CLEAR = Bit3 | Bit0,
};
// GYRO_CONFIG1
enum GYRO_CONFIG1_BIT : uint8_t {
GYRO_UI_FILT_ORD = Bit3 | Bit2, // 00: 1st Order
};
// GYRO_ACCEL_CONFIG0
enum GYRO_ACCEL_CONFIG0_BIT : uint8_t {
// 7:4 ACCEL_UI_FILT_BW
ACCEL_UI_FILT_BW = Bit7 | Bit6 | Bit5 | Bit4, // 0: BW=ODR/2
// 3:0 GYRO_UI_FILT_BW
GYRO_UI_FILT_BW = Bit3 | Bit2 | Bit1 | Bit0, // 0: BW=ODR/2
};
// ACCEL_CONFIG1
enum ACCEL_CONFIG1_BIT : uint8_t {
ACCEL_UI_FILT_ORD = Bit4 | Bit3, // 00: 1st Order
};
// FIFO_CONFIG1
enum FIFO_CONFIG1_BIT : uint8_t {
FIFO_RESUME_PARTIAL_RD = Bit6,
FIFO_WM_GT_TH = Bit5,
FIFO_HIRES_EN = Bit4,
FIFO_TEMP_EN = Bit2,
FIFO_GYRO_EN = Bit1,
FIFO_ACCEL_EN = Bit0,
};
// INT_CONFIG0
enum INT_CONFIG0_BIT : uint8_t {
// 3:2 FIFO_THS_INT_CLEAR
CLEAR_ON_FIFO_READ = Bit3,
};
// INT_SOURCE0
enum INT_SOURCE0_BIT : uint8_t {
UI_FSYNC_INT1_EN = Bit6,
PLL_RDY_INT1_EN = Bit5,
RESET_DONE_INT1_EN = Bit4,
UI_DRDY_INT1_EN = Bit3,
FIFO_THS_INT1_EN = Bit2, // FIFO threshold interrupt routed to INT1
FIFO_FULL_INT1_EN = Bit1,
UI_AGC_RDY_INT1_EN = Bit0,
};
// REG_BANK_SEL
enum REG_BANK_SEL_BIT : uint8_t {
USER_BANK_0 = 0, // 0: Select USER BANK 0.
USER_BANK_1 = Bit0, // 1: Select USER BANK 1.
USER_BANK_2 = Bit1, // 2: Select USER BANK 2.
USER_BANK_3 = Bit1 | Bit0, // 3: Select USER BANK 3.
};
//---------------- BANK1 Register bits
// GYRO_CONFIG_STATIC2
enum GYRO_CONFIG_STATIC2_BIT : uint8_t {
GYRO_AAF_DIS = Bit1,
GYRO_NF_DIS = Bit0,
};
// GYRO_CONFIG_STATIC3
enum GYRO_CONFIG_STATIC3_BIT : uint8_t {
// 585 Hz
GYRO_AAF_DELT_SET = Bit3 | Bit2 | Bit0, //13
GYRO_AAF_DELT_CLEAR = Bit5 | Bit4 | Bit1,
// 213 Hz
// GYRO_AAF_DELT_SET = Bit2 | Bit0, //5
// GYRO_AAF_DELT_CLEAR = Bit5 | Bit4 | Bit3 | Bit1,
// 126 Hz
//GYRO_AAF_DELT_SET = Bit1 | Bit0, //3
//GYRO_AAF_DELT_CLEAR = Bit5 | Bit4 | Bit3 | Bit2,
// 42 Hz
// GYRO_AAF_DELT_SET = Bit0, //1
// GYRO_AAF_DELT_CLEAR = Bit5 | Bit4 | Bit3 | Bit2 | Bit1,
};
// GYRO_CONFIG_STATIC4
enum GYRO_CONFIG_STATIC4_BIT : uint8_t {
// 585 Hz
GYRO_AAF_DELTSQR_LOW_SET = Bit7 | Bit5 | Bit3 | Bit1, //170
GYRO_AAF_DELTSQR_LOW_CLEAR = Bit6 | Bit4 | Bit2 | Bit0,
// 213 Hz
// GYRO_AAF_DELTSQR_LOW_SET = Bit4 | Bit3 | Bit0, //25
// GYRO_AAF_DELTSQR_LOW_CLEAR = Bit7 | Bit6 | Bit5 | Bit2 | Bit1,
// 126 Hz
//GYRO_AAF_DELTSQR_LOW_SET = Bit3 | Bit0, //9
//GYRO_AAF_DELTSQR_LOW_CLEAR = Bit7 | Bit6 | Bit5 | Bit4 | Bit2 | Bit1,
// 42 Hz
// GYRO_AAF_DELTSQR_LOW_SET = Bit0, //1
// GYRO_AAF_DELTSQR_LOW_CLEAR = Bit7 | Bit6 | Bit5 | Bit4 | Bit3 | Bit2 | Bit1,
};
// GYRO_CONFIG_STATIC5
enum GYRO_CONFIG_STATIC5_BIT : uint8_t {
// 585 Hz
GYRO_AAF_DELTSQR_HIGH_SET = 0,
GYRO_AAF_DELTSQR_HIGH_CLEAR = Bit3 | Bit2 | Bit1 | Bit0,
GYRO_AAF_BITSHIFT_SET = Bit7, // 8 << 4
GYRO_AAF_BITSHIFT_CLEAR = Bit6 | Bit5 | Bit4,
// 213 Hz
// GYRO_AAF_DELTSQR_HIGH_SET = 0,
// GYRO_AAF_DELTSQR_HIGH_CLEAR = Bit3 | Bit2 | Bit1 | Bit0,
// GYRO_AAF_BITSHIFT_SET = Bit7 | Bit5, //10
// GYRO_AAF_BITSHIFT_CLEAR = Bit6 | Bit4,
// 126 Hz
// GYRO_AAF_BITSHIFT_SET = Bit7 | Bit6, //12
// GYRO_AAF_BITSHIFT_CLEAR = Bit5 | Bit4,
// 42 Hz
// GYRO_AAF_BITSHIFT_SET = Bit7 | Bit6 | Bit5 | Bit4, //15
// GYRO_AAF_BITSHIFT_CLEAR = 0,
};
//---------------- BANK2 Register bits
// ACCEL_CONFIG_STATIC2
enum ACCEL_CONFIG_STATIC2_BIT : uint8_t {
ACCEL_AAF_DIS = Bit0,
ACCEL_AAF_DELT = Bit3 | Bit1,
// 213 Hz
ACCEL_AAF_DELT_SET = Bit3 | Bit1, //5
ACCEL_AAF_DELT_CLEAR = Bit6 | Bit5 | Bit4 | Bit2,
// 42 Hz
// ACCEL_AAF_DELT_SET = Bit1, //1
// ACCEL_AAF_DELT_CLEAR = Bit6 | Bit5 | Bit4 | Bit3 | Bit2,
};
// ACCEL_CONFIG_STATIC3
enum ACCEL_CONFIG_STATIC3_BIT : uint8_t {
ACCEL_AAF_DELTSQR_LOW = Bit4 | Bit3 | Bit0,
// 213 Hz
ACCEL_AAF_DELTSQR_LOW_SET = Bit4 | Bit3 | Bit0, //25
ACCEL_AAF_DELTSQR_LOW_CLEAR = Bit7 | Bit6 | Bit5 | Bit2 | Bit1,
// 42 Hz
// ACCEL_AAF_DELTSQR_LOW_SET = Bit0, //1
// ACCEL_AAF_DELTSQR_LOW_CLEAR = Bit7 | Bit6 | Bit5 | Bit4 | Bit3 | Bit2 | Bit1,
};
// ACCEL_CONFIG_STATIC4
enum ACCEL_CONFIG_STATIC4_BIT : uint8_t {
ACCEL_AAF_BITSHIFT = Bit7 | Bit5,
ACCEL_AAF_DELTSQR_HIGH = 0,
// 213 Hz
ACCEL_AAF_BITSHIFT_SET = Bit7 | Bit5, //10
ACCEL_AAF_BITSHIFT_CLEAR = Bit6 | Bit4,
// 42 Hz
// ACCEL_AAF_BITSHIFT_SET = Bit7 | Bit6 | Bit5 | Bit4, //15
// ACCEL_AAF_BITSHIFT_CLEAR = 0,
ACCEL_AAF_DELTSQR_HIGH_SET = 0,
ACCEL_AAF_DELTSQR_HIGH_CLEAR = Bit3 | Bit2 | Bit1 | Bit0,
};
namespace FIFO
{
static constexpr size_t SIZE = 2048;
// FIFO_DATA layout when FIFO_CONFIG1 has FIFO_GYRO_EN and FIFO_ACCEL_EN set
// Packet 4
struct DATA {
uint8_t FIFO_Header;
uint8_t ACCEL_DATA_X1; // Accel X [19:12]
uint8_t ACCEL_DATA_X0; // Accel X [11:4]
uint8_t ACCEL_DATA_Y1; // Accel Y [19:12]
uint8_t ACCEL_DATA_Y0; // Accel Y [11:4]
uint8_t ACCEL_DATA_Z1; // Accel Z [19:12]
uint8_t ACCEL_DATA_Z0; // Accel Z [11:4]
uint8_t GYRO_DATA_X1; // Gyro X [19:12]
uint8_t GYRO_DATA_X0; // Gyro X [11:4]
uint8_t GYRO_DATA_Y1; // Gyro Y [19:12]
uint8_t GYRO_DATA_Y0; // Gyro Y [11:4]
uint8_t GYRO_DATA_Z1; // Gyro Z [19:12]
uint8_t GYRO_DATA_Z0; // Gyro Z [11:4]
uint8_t TEMP_DATA1; // Temperature[15:8]
uint8_t TEMP_DATA0; // Temperature[7:0]
uint8_t TimeStamp_h; // TimeStamp[15:8]
uint8_t TimeStamp_l; // TimeStamp[7:0]
uint8_t Ext_Accel_X_Gyro_X; // Accel X [3:0] Gyro X [3:0]
uint8_t Ext_Accel_Y_Gyro_Y; // Accel Y [3:0] Gyro Y [3:0]
uint8_t Ext_Accel_Z_Gyro_Z; // Accel Z [3:0] Gyro Z [3:0]
};
// With FIFO_ACCEL_EN and FIFO_GYRO_EN header should be 8b_0110_10xx
enum FIFO_HEADER_BIT : uint8_t {
HEADER_MSG = Bit7, // 1: FIFO is empty
HEADER_ACCEL = Bit6, // 1: Packet is sized so that accel data have location in the packet, FIFO_ACCEL_EN must be 1
HEADER_GYRO = Bit5, // 1: Packet is sized so that gyro data have location in the packet, FIFO_GYRO_EN must be1
HEADER_20 = Bit4, // 1: Packet has a new and valid sample of extended 20-bit data for gyro and/or accel
HEADER_TIMESTAMP_FSYNC = Bit3 | Bit2,
HEADER_ODR_ACCEL = Bit1, // 1: The ODR for accel is different for this accel data packet compared to the previous accel packet
HEADER_ODR_GYRO = Bit0, // 1: The ODR for gyro is different for this gyro data packet compared to the previous gyro packet
};
}
} // namespace InvenSense_ICM42688P

116
boards/modalai/voxl2-slpi/src/drivers/icm42688p/icm42688p_main.cpp Normal file
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@ -0,0 +1,116 @@
/****************************************************************************
*
* Copyright (c) 2020 PX4 Development Team. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
#include "ICM42688P.hpp"
#include <px4_platform_common/getopt.h>
#include <px4_platform_common/module.h>
#include <string>
void ICM42688P::print_usage()
{
PRINT_MODULE_USAGE_NAME("icm42688p", "driver");
PRINT_MODULE_USAGE_SUBCATEGORY("imu");
PRINT_MODULE_USAGE_COMMAND("start");
PRINT_MODULE_USAGE_PARAMS_I2C_SPI_DRIVER(false, true);
PRINT_MODULE_USAGE_PARAM_INT('R', 0, 0, 35, "Rotation", true);
PRINT_MODULE_USAGE_DEFAULT_COMMANDS();
}
// I2CSPIDriverBase *ICM42688P::instantiate(const BusCLIArguments &cli, const BusInstanceIterator &iterator,
// int runtime_instance)
// {
// ICM42688P *instance = new ICM42688P(iterator.configuredBusOption(), iterator.bus(), iterator.devid(), cli.rotation,
// cli.bus_frequency, cli.spi_mode, iterator.DRDYGPIO());
//
// if (!instance) {
// PX4_ERR("alloc failed");
// return nullptr;
// }
//
// if (OK != instance->init()) {
// delete instance;
// return nullptr;
// }
//
// return instance;
// }
extern "C" int icm42688p_main(int argc, char *argv[])
{
for (int i = 0; i <= argc - 1; i++) {
if (std::string(argv[i]) == "-h") {
argv[i] = 0;
hitl_mode = true;
break;
}
}
int ch;
using ThisDriver = ICM42688P;
BusCLIArguments cli{false, true};
cli.default_spi_frequency = SPI_SPEED;
while ((ch = cli.getOpt(argc, argv, "R:")) != EOF) {
switch (ch) {
case 'R':
cli.rotation = (enum Rotation)atoi(cli.optArg());
break;
}
}
const char *verb = cli.optArg();
if (!verb) {
ThisDriver::print_usage();
return -1;
}
BusInstanceIterator iterator(MODULE_NAME, cli, DRV_IMU_DEVTYPE_ICM42688P);
if (!strcmp(verb, "start")) {
return ThisDriver::module_start(cli, iterator);
}
if (!strcmp(verb, "stop")) {
return ThisDriver::module_stop(iterator);
}
if (!strcmp(verb, "status")) {
return ThisDriver::module_status(iterator);
}
ThisDriver::print_usage();
return -1;
}

40
boards/modalai/voxl2-slpi/src/spi.cpp Normal file
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@ -0,0 +1,40 @@
/****************************************************************************
*
* Copyright (C) 2020 PX4 Development Team. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
#include <px4_arch/spi_hw_description.h>
#include <px4_platform_common/spi.h>
#include <drivers/drv_sensor.h>
constexpr px4_spi_bus_t px4_spi_buses[SPI_BUS_MAX_BUS_ITEMS] = {
initSPIBus(1, {initSPIDevice(DRV_IMU_DEVTYPE_ICM42688P), }),
};

1
boards/modalai/voxl2/default.px4board
View File

@ -7,3 +7,4 @@ CONFIG_SYSTEMCMDS_UORB=y
CONFIG_ORB_COMMUNICATOR=y CONFIG_ORB_COMMUNICATOR=y
CONFIG_SYSTEMCMDS_PARAM=y CONFIG_SYSTEMCMDS_PARAM=y
CONFIG_DRIVERS_QSHELL_POSIX=y CONFIG_DRIVERS_QSHELL_POSIX=y
CONFIG_SYSTEMCMDS_TOPIC_LISTENER=y

2
boards/modalai/voxl2/target/voxl-px4.config
View File

@ -17,3 +17,5 @@ if [ $TESTMODE = "ON" ]; then
fi fi
muorb start muorb start
qshell icm42688p start -s

2
platforms/common/include/px4_platform_common/tasks.h
View File

@ -59,7 +59,7 @@ typedef int px4_task_t;
#define px4_task_exit(x) _exit(x) #define px4_task_exit(x) _exit(x)
#elif defined(__PX4_POSIX) || defined(__PX4_QURT) #elif defined(__PX4_POSIX)
#include <pthread.h> #include <pthread.h>
#include <sched.h> #include <sched.h>

2
platforms/common/include/px4_platform_common/time.h
View File

@ -5,7 +5,7 @@
#include <time.h> #include <time.h>
#include <pthread.h> #include <pthread.h>
#if defined(__PX4_POSIX) || defined(__PX4_QURT) #if defined(__PX4_POSIX)
__BEGIN_DECLS __BEGIN_DECLS
__EXPORT int px4_clock_gettime(clockid_t clk_id, struct timespec *tp); __EXPORT int px4_clock_gettime(clockid_t clk_id, struct timespec *tp);
__END_DECLS __END_DECLS

2
platforms/common/spi.cpp
View File

@ -71,7 +71,7 @@ const px4_spi_bus_t *px4_spi_buses{nullptr};
int px4_find_spi_bus(uint32_t devid) int px4_find_spi_bus(uint32_t devid)
{ {
for (int i = 0; px4_spi_buses != nullptr && i < SPI_BUS_MAX_BUS_ITEMS; ++i) { for (int i = 0; (px4_spi_bus_t *) px4_spi_buses != nullptr && i < SPI_BUS_MAX_BUS_ITEMS; ++i) {
const px4_spi_bus_t &bus_data = px4_spi_buses[i]; const px4_spi_bus_t &bus_data = px4_spi_buses[i];
if (bus_data.bus == -1) { if (bus_data.bus == -1) {

5
platforms/common/work_queue/hrt_queue.c
View File

@ -126,15 +126,10 @@ int hrt_work_queue(struct work_s *work, worker_t worker, void *arg, uint32_t del
dq_addlast(&work->dq, &wqueue->q); dq_addlast(&work->dq, &wqueue->q);
if (px4_getpid() != wqueue->pid) { /* only need to wake up if called from a different thread */ if (px4_getpid() != wqueue->pid) { /* only need to wake up if called from a different thread */
#ifdef __PX4_QURT
px4_task_kill(wqueue->pid, SIGALRM); /* Wake up the worker thread */
#else
//wqueue->pid == own task? -> don't signal //wqueue->pid == own task? -> don't signal
px4_task_kill(wqueue->pid, SIGCONT); /* Wake up the worker thread */ px4_task_kill(wqueue->pid, SIGCONT); /* Wake up the worker thread */
#endif
} }
hrt_work_unlock(); hrt_work_unlock();
return PX4_OK; return PX4_OK;
} }

14
platforms/common/work_queue/hrt_thread.c
View File

@ -138,6 +138,16 @@ static void hrt_work_process()
/* Default to sleeping for 1 sec */ /* Default to sleeping for 1 sec */
next = 1000000; next = 1000000;
#ifdef __PX4_QURT
// In Posix certain signals wake up a sleeping thread but it isn't the case
// with the Qurt POSIX implementation. So rather than assume we can come out
// of the sleep early by a signal we just wake up more often. The best way to
// fix this would be to move to a px4_sem_timedwait. But the current implementation
// of that function on Qurt uses this hrt_thread! So, it would all have to be
// re-written to use Qurt semaphores which do have timed waits.
next = 1000;
#endif
hrt_work_lock(); hrt_work_lock();
work = (struct work_s *)wqueue->q.head; work = (struct work_s *)wqueue->q.head;
@ -287,9 +297,5 @@ void hrt_work_queue_init(void)
(char *const *)NULL); (char *const *)NULL);
#ifdef __PX4_QURT
signal(SIGALRM, _sighandler);
#else
signal(SIGCONT, _sighandler); signal(SIGCONT, _sighandler);
#endif
} }

5
platforms/common/work_queue/work_queue.c
View File

@ -41,6 +41,7 @@
#include <px4_platform_common/defines.h> #include <px4_platform_common/defines.h>
#include <px4_platform_common/workqueue.h> #include <px4_platform_common/workqueue.h>
#include <px4_platform_common/tasks.h> #include <px4_platform_common/tasks.h>
#include <px4_platform_common/posix.h>
#include <signal.h> #include <signal.h>
#include <stdint.h> #include <stdint.h>
@ -125,11 +126,7 @@ int work_queue(int qid, struct work_s *work, worker_t worker, void *arg, uint32_
work->qtime = clock_systimer(); /* Time work queued */ work->qtime = clock_systimer(); /* Time work queued */
dq_addlast((dq_entry_t *)work, &wqueue->q); dq_addlast((dq_entry_t *)work, &wqueue->q);
#ifdef __PX4_QURT
px4_task_kill(wqueue->pid, SIGALRM); /* Wake up the worker thread */
#else
px4_task_kill(wqueue->pid, SIGCONT); /* Wake up the worker thread */ px4_task_kill(wqueue->pid, SIGCONT); /* Wake up the worker thread */
#endif
work_unlock(qid); work_unlock(qid);
return PX4_OK; return PX4_OK;

1
platforms/qurt/cmake/px4_impl_os.cmake
View File

@ -200,6 +200,7 @@ function(px4_os_prebuild_targets)
ARGN ${ARGN}) ARGN ${ARGN})
add_library(prebuild_targets INTERFACE) add_library(prebuild_targets INTERFACE)
target_link_libraries(prebuild_targets INTERFACE drivers_board)
add_dependencies(prebuild_targets DEPENDS uorb_headers) add_dependencies(prebuild_targets DEPENDS uorb_headers)
endfunction() endfunction()

1
platforms/qurt/cmake/qurt_reqs.cmake
View File

@ -99,6 +99,7 @@ set(ARCHCPUFLAGS
add_definitions( add_definitions(
-D __QURT -D __QURT
# -D DEBUG_BUILD # Add this to get extra debug output
-D _PROVIDE_POSIX_TIME_DECLS -D _PROVIDE_POSIX_TIME_DECLS
-D _HAS_C9X -D _HAS_C9X
-D restrict=__restrict__ -D restrict=__restrict__

62
platforms/qurt/include/hrt_work.h Normal file
View File

@ -0,0 +1,62 @@
/****************************************************************************
*
* Copyright (C) 2015 Mark Charlebois. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
#include <px4_platform_common/log.h>
#include <px4_platform_common/posix.h>
#include <semaphore.h>
#include <px4_platform_common/workqueue.h>
#pragma once
__BEGIN_DECLS
extern px4_sem_t _hrt_work_lock;
extern struct wqueue_s g_hrt_work;
void hrt_work_queue_init(void);
int hrt_work_queue(struct work_s *work, worker_t worker, void *arg, uint32_t usdelay);
void hrt_work_cancel(struct work_s *work);
static inline void hrt_work_lock(void);
static inline void hrt_work_lock()
{
px4_sem_wait(&_hrt_work_lock);
}
static inline void hrt_work_unlock(void);
static inline void hrt_work_unlock()
{
px4_sem_post(&_hrt_work_lock);
}
__END_DECLS

60
platforms/qurt/include/px4_arch/spi_hw_description.h Normal file
View File

@ -0,0 +1,60 @@
/****************************************************************************
*
* Copyright (C) 2020 PX4 Development Team. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
#pragma once
#include <px4_platform_common/spi.h>
static inline constexpr px4_spi_bus_device_t initSPIDevice(uint8_t devid_driver)
{
px4_spi_bus_device_t ret{};
ret.cs_gpio = 1; // set to some non-zero value to indicate this is used
ret.drdy_gpio = 1;
ret.devid = PX4_SPIDEV_ID(PX4_SPI_DEVICE_ID, 0);
ret.devtype_driver = devid_driver;
return ret;
}
static inline constexpr px4_spi_bus_t initSPIBus(int bus, const px4_spi_bus_devices_t &devices)
{
px4_spi_bus_t ret{};
for (int i = 0; i < SPI_BUS_MAX_DEVICES; ++i) {
ret.devices[i] = devices.devices[i];
}
ret.bus = bus;
ret.is_external = false; // all buses are marked internal on QuRT
ret.requires_locking = false;
return ret;
}

1
platforms/qurt/src/px4/CMakeLists.txt
View File

@ -44,3 +44,4 @@ add_library(px4_layer
) )
target_link_libraries(px4_layer PRIVATE work_queue) target_link_libraries(px4_layer PRIVATE work_queue)
target_link_libraries(px4_layer PRIVATE drivers_board)

19
platforms/qurt/src/px4/tasks.cpp
View File

@ -66,6 +66,14 @@ static task_entry_t taskmap[PX4_MAX_TASKS];
static bool task_mutex_initialized = false; static bool task_mutex_initialized = false;
static pthread_mutex_t task_mutex; static pthread_mutex_t task_mutex;
// These are some Qurt pthread stubs needed for compilation and linking
extern "C" {
int pthread_setname_np(pthread_t __target_thread, const char *__name) { return 0; }
int pthread_attr_setschedpolicy(pthread_attr_t *attr, int policy) { return 0; }
}
static void *entry_adapter(void *ptr) static void *entry_adapter(void *ptr)
{ {
task_entry_t *data; task_entry_t *data;
@ -147,11 +155,12 @@ static px4_task_t px4_task_spawn_internal(const char *name, int priority, px4_ma
return -1; return -1;
} }
priority = 255 - priority; // Qurt threads have different priority numbers. 1 is the highest
// priority and 254 is the lowest. But we are using the pthread
if (priority < 5) { priority = 5; } // implementation on Qurt which returns 255 when you call sched_get_priority_max.
// So, the big assumption is that the Qurt pthread implementation deals with
if (priority > 250) { priority = 250; } // this properly when creating the underlying Qurt task.
// TODO: Needs to be verified!
if (strlen(name) >= PX4_TASK_MAX_NAME_LENGTH) { if (strlen(name) >= PX4_TASK_MAX_NAME_LENGTH) {
pthread_mutex_unlock(&task_mutex); pthread_mutex_unlock(&task_mutex);

4
src/lib/drivers/device/CMakeLists.txt
View File

@ -41,9 +41,9 @@ if (${PX4_PLATFORM} STREQUAL "nuttx")
list(APPEND SRCS_PLATFORM nuttx/SPI.cpp) list(APPEND SRCS_PLATFORM nuttx/SPI.cpp)
endif() endif()
elseif((${PX4_PLATFORM} MATCHES "qurt")) elseif((${PX4_PLATFORM} MATCHES "qurt"))
list(APPEND SRCS_PLATFORM qurt/I2C.cpp) # list(APPEND SRCS_PLATFORM qurt/I2C.cpp)
list(APPEND SRCS_PLATFORM qurt/SPI.cpp) list(APPEND SRCS_PLATFORM qurt/SPI.cpp)
list(APPEND SRCS_PLATFORM qurt/uart.c) # list(APPEND SRCS_PLATFORM qurt/uart.c)
elseif(UNIX AND NOT APPLE) #TODO: add linux PX4 platform type elseif(UNIX AND NOT APPLE) #TODO: add linux PX4 platform type
# Linux I2Cdev and SPIdev # Linux I2Cdev and SPIdev
list(APPEND SRCS_PLATFORM list(APPEND SRCS_PLATFORM

17
src/modules/muorb/slpi/uORBProtobufChannel.cpp
View File

@ -37,9 +37,14 @@
#include <string> #include <string>
#include <drivers/drv_hrt.h> #include <drivers/drv_hrt.h>
#include <drivers/device/spi.h>
#include <pthread.h> #include <pthread.h>
#include <px4_platform_common/tasks.h> #include <px4_platform_common/tasks.h>
#include <px4_platform_common/log.h> #include <px4_platform_common/log.h>
#include <lib/parameters/param.h>
#include <px4_platform_common/px4_work_queue/WorkQueueManager.hpp>
#include "hrt_work.h"
// Definition of test to run when in muorb test mode // Definition of test to run when in muorb test mode
static MUORBTestType test_to_run; static MUORBTestType test_to_run;
@ -230,6 +235,18 @@ int px4muorb_orb_initialize(fc_func_ptrs *func_ptrs, int32_t clock_offset_us)
uORB::Manager::get_instance()->set_uorb_communicator( uORB::Manager::get_instance()->set_uorb_communicator(
uORB::ProtobufChannel::GetInstance()); uORB::ProtobufChannel::GetInstance());
param_init();
px4::WorkQueueManagerStart();
// Configure the SPI driver function pointers
device::SPI::configure_callbacks(muorb_func_ptrs._config_spi_bus_func_t, muorb_func_ptrs._spi_transfer_func_t);
// Initialize the interrupt callback registration
register_interrupt_callback_initalizer(muorb_func_ptrs.register_interrupt_callback);
hrt_work_queue_init();
const char *argv[3] = { "slpi", "start" }; const char *argv[3] = { "slpi", "start" };
int argc = 2; int argc = 2;