esp32_BNO08x/test/MultiReportTests.cpp

/**
 * @file MultiReportTests.cpp
 * @author Myles Parfeniuk
 *
 *
 * @warning YOU MUST ADD THE FOLLOWING LINE TO YOUR MAIN PROJECTS CMakeLists.txt IN ORDER FOR THIS TEST SUITE TO BE BUILT WITH PROJECT:
 *          set(TEST_COMPONENTS "esp32_BNO08x" CACHE STRING "Components to test.")
 */

#include "unity.h"
#include "../include/BNO08xTestHelper.hpp"

TEST_CASE("BNO08x Driver Creation for [MultiReportEnableDisable] Tests", "[MultiReportEnableDisable]")
{
    const constexpr char* TEST_TAG = "BNO08x Driver Creation for [MultiReportEnableDisable] Tests";
    BNO08x* imu = nullptr;

    BNO08xTestHelper::print_test_start_banner(TEST_TAG);

    BNO08xTestHelper::print_test_msg(TEST_TAG, "Creating & initializing BNO08x driver.");
    BNO08xTestHelper::create_test_imu();
    imu = BNO08xTestHelper::get_test_imu();

    // ensure IMU initialized successfully
    TEST_ASSERT_EQUAL(true, imu->initialize());
    BNO08xTestHelper::print_test_end_banner(TEST_TAG);
}

TEST_CASE("Enable/Disable Dual Report", "[MultiReportEnableDisable]")
{
    const constexpr char* TEST_TAG = "Enable/Disable Dual Report";
    static const constexpr uint8_t ENABLED_REPORT_COUNT = 2;
    static const constexpr uint8_t RX_REPORT_TRIAL_CNT = ENABLED_REPORT_COUNT * 5;
    static const constexpr uint32_t REPORT_PERIOD = 100000UL; // 100ms

    BNO08x* imu = nullptr;
    char msg_buff[200] = {};
    bool data_available = false;
    bool data_available_accel = false;
    bool data_available_lin_accel = false;

    bno08x_accel_t data;

    BNO08xTestHelper::print_test_start_banner(TEST_TAG);

    imu = BNO08xTestHelper::get_test_imu();

    TEST_ASSERT_EQUAL(true, imu->accelerometer.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.enable(REPORT_PERIOD));

    for (int i = 0; i < RX_REPORT_TRIAL_CNT; i++)
    {
        data_available = imu->data_available();
        TEST_ASSERT_EQUAL(true, data_available);

        if (imu->accelerometer.has_new_data())
        {
            data_available_accel = true;
            data = imu->accelerometer.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: Accel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data.x, data.y, data.z,
                    BNO08x::accuracy_to_str(data.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->linear_accelerometer.has_new_data())
        {
            data_available_lin_accel = true;
            data = imu->linear_accelerometer.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: LinAccel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data.x, data.y, data.z,
                    BNO08x::accuracy_to_str(data.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }
    }

    TEST_ASSERT_EQUAL(true, imu->accelerometer.disable());
    TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.disable());

    TEST_ASSERT_EQUAL(true, data_available_accel);
    TEST_ASSERT_EQUAL(true, data_available_lin_accel);

    BNO08xTestHelper::print_test_end_banner(TEST_TAG);
}

TEST_CASE("Enable/Disable Quad Report", "[MultiReportEnableDisable]")
{
    const constexpr char* TEST_TAG = "Enable/Disable Quad Report";
    static const constexpr uint8_t ENABLED_REPORT_COUNT = 4;
    static const constexpr uint8_t RX_REPORT_TRIAL_CNT = ENABLED_REPORT_COUNT * 5;
    static const constexpr uint32_t REPORT_PERIOD = 100000UL; // 100ms

    BNO08x* imu = nullptr;
    char msg_buff[200] = {};
    bool data_available = false;
    bool data_available_accel = false;
    bool data_available_lin_accel = false;
    bool data_available_gravity = false;
    bool data_available_cal_gyro = false;

    bno08x_accel_t data_accel;
    bno08x_gyro_t data_vel;

    BNO08xTestHelper::print_test_start_banner(TEST_TAG);

    imu = BNO08xTestHelper::get_test_imu();

    TEST_ASSERT_EQUAL(true, imu->accelerometer.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->gravity.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->cal_gyro.enable(REPORT_PERIOD));

    for (int i = 0; i < RX_REPORT_TRIAL_CNT; i++)
    {
        data_available = imu->data_available();
        TEST_ASSERT_EQUAL(true, data_available);

        if (imu->accelerometer.has_new_data())
        {
            data_available_accel = true;
            data_accel = imu->accelerometer.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: Accel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,
                    data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->linear_accelerometer.has_new_data())
        {
            data_available_lin_accel = true;
            data_accel = imu->linear_accelerometer.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: LinAccel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x,
                    data_accel.y, data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->gravity.has_new_data())
        {
            data_available_gravity = true;
            data_accel = imu->gravity.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: Gravity: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,
                    data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->cal_gyro.has_new_data())
        {
            data_available_cal_gyro = true;
            data_vel = imu->cal_gyro.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: CalGyro: [rad/s] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_vel.x, data_vel.y,
                    data_vel.z, BNO08x::accuracy_to_str(data_vel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }
    }

    TEST_ASSERT_EQUAL(true, imu->accelerometer.disable());
    TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.disable());
    TEST_ASSERT_EQUAL(true, imu->gravity.disable());
    TEST_ASSERT_EQUAL(true, imu->cal_gyro.disable());

    TEST_ASSERT_EQUAL(true, data_available_accel);
    TEST_ASSERT_EQUAL(true, data_available_lin_accel);
    TEST_ASSERT_EQUAL(true, data_available_gravity);
    TEST_ASSERT_EQUAL(true, data_available_cal_gyro);

    BNO08xTestHelper::print_test_end_banner(TEST_TAG);
}

TEST_CASE("Enable/Disable Octo Report", "[MultiReportEnableDisable]")
{
    const constexpr char* TEST_TAG = "Enable/Disable Octo Report";
    static const constexpr uint8_t ENABLED_REPORT_COUNT = 8;
    static const constexpr uint8_t RX_REPORT_TRIAL_CNT = ENABLED_REPORT_COUNT * 5;
    static const constexpr uint32_t REPORT_PERIOD = 100000UL; // 100ms

    BNO08x* imu = nullptr;
    char msg_buff[200] = {};
    bool data_available = false;
    bool data_available_accel = false;
    bool data_available_lin_accel = false;
    bool data_available_gravity = false;
    bool data_available_cal_gyro = false;
    bool data_available_cal_magnetometer = false;
    bool data_available_rv = false;
    bool data_available_rv_game = false;
    bool data_available_rv_geomagnetic = false;

    bno08x_accel_t data_accel;
    bno08x_gyro_t data_vel;
    bno08x_magf_t data_magf;
    bno08x_quat_t data_quat;

    BNO08xTestHelper::print_test_start_banner(TEST_TAG);

    imu = BNO08xTestHelper::get_test_imu();

    TEST_ASSERT_EQUAL(true, imu->accelerometer.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->gravity.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->cal_gyro.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->cal_magnetometer.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->rv.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->rv_game.enable(REPORT_PERIOD));
    TEST_ASSERT_EQUAL(true, imu->rv_geomagnetic.enable(REPORT_PERIOD));

    for (int i = 0; i < RX_REPORT_TRIAL_CNT; i++)
    {
        data_available = imu->data_available();
        TEST_ASSERT_EQUAL(true, data_available);

        if (imu->accelerometer.has_new_data())
        {
            data_available_accel = true;
            data_accel = imu->accelerometer.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: Accel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,
                    data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->linear_accelerometer.has_new_data())
        {
            data_available_lin_accel = true;
            data_accel = imu->linear_accelerometer.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: LinAccel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x,
                    data_accel.y, data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->gravity.has_new_data())
        {
            data_available_gravity = true;
            data_accel = imu->gravity.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: Gravity: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,
                    data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->cal_gyro.has_new_data())
        {
            data_available_cal_gyro = true;
            data_vel = imu->cal_gyro.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: CalGyro: [rad/s] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_vel.x, data_vel.y,
                    data_vel.z, BNO08x::accuracy_to_str(data_vel.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->cal_magnetometer.has_new_data())
        {
            data_available_cal_magnetometer = true;
            data_magf = imu->cal_magnetometer.get();
            sprintf(msg_buff, "Rx Data Trial %d Success: CalMagnetometer: [uTesla] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_magf.x,
                    data_magf.y, data_magf.z, BNO08x::accuracy_to_str(data_magf.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->rv.has_new_data())
        {
            data_available_rv = true;
            data_quat = imu->rv.get_quat();
            sprintf(msg_buff, "Rx Data Trial %d Success: RV: [n/a] real: %.2f i: %.2f j: %.2f k: %.2f accuracy: %s ", (i + 1), data_quat.real,
                    data_quat.i, data_quat.j, data_quat.k, BNO08x::accuracy_to_str(data_quat.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->rv_game.has_new_data())
        {
            data_available_rv_game = true;
            data_quat = imu->rv_game.get_quat();
            sprintf(msg_buff, "Rx Data Trial %d Success: RV Game: [n/a] real: %.2f i: %.2f j: %.2f k: %.2f accuracy: %s ", (i + 1), data_quat.real,
                    data_quat.i, data_quat.j, data_quat.k, BNO08x::accuracy_to_str(data_quat.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }

        if (imu->rv_geomagnetic.has_new_data())
        {
            data_available_rv_geomagnetic = true;
            data_quat = imu->rv_geomagnetic.get_quat();
            sprintf(msg_buff, "Rx Data Trial %d Success: RV Geomagnetic: [n/a] real: %.2f i: %.2f j: %.2f k: %.2f accuracy: %s ", (i + 1),
                    data_quat.real, data_quat.i, data_quat.j, data_quat.k, BNO08x::accuracy_to_str(data_quat.accuracy));
            BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);
        }
    }

    TEST_ASSERT_EQUAL(true, imu->accelerometer.disable());
    TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.disable());
    TEST_ASSERT_EQUAL(true, imu->gravity.disable());
    TEST_ASSERT_EQUAL(true, imu->cal_gyro.disable());
    TEST_ASSERT_EQUAL(true, imu->cal_magnetometer.disable());
    TEST_ASSERT_EQUAL(true, imu->rv.disable());
    TEST_ASSERT_EQUAL(true, imu->rv_game.disable());
    TEST_ASSERT_EQUAL(true, imu->rv_geomagnetic.disable());

    TEST_ASSERT_EQUAL(true, data_available_accel);
    TEST_ASSERT_EQUAL(true, data_available_lin_accel);
    TEST_ASSERT_EQUAL(true, data_available_gravity);
    TEST_ASSERT_EQUAL(true, data_available_cal_gyro);
    TEST_ASSERT_EQUAL(true, data_available_cal_magnetometer);
    TEST_ASSERT_EQUAL(true, data_available_rv);
    TEST_ASSERT_EQUAL(true, data_available_rv_game);
    TEST_ASSERT_EQUAL(true, data_available_rv_geomagnetic);

    BNO08xTestHelper::print_test_end_banner(TEST_TAG);
}

TEST_CASE("BNO08x Driver Cleanup for [MultiReportEnableDisable] Tests", "[MultiReportEnableDisable]")
{
    const constexpr char* TEST_TAG = "BNO08x Driver Cleanup for [MultiReportEnableDisable] Tests";

    BNO08xTestHelper::print_test_start_banner(TEST_TAG);
    BNO08xTestHelper::print_test_msg(TEST_TAG, "Destroying BNO08x Driver.");

    BNO08xTestHelper::destroy_test_imu();
    BNO08xTestHelper::print_test_end_banner(TEST_TAG);
}
return of the test + more documentation 2024-11-27 23:54:47 +00:00			`/**`
			`* @file MultiReportTests.cpp`
			`* @author Myles Parfeniuk`
			`*`
			`*`
			`* @warning YOU MUST ADD THE FOLLOWING LINE TO YOUR MAIN PROJECTS CMakeLists.txt IN ORDER FOR THIS TEST SUITE TO BE BUILT WITH PROJECT:`
			`* set(TEST_COMPONENTS "esp32_BNO08x" CACHE STRING "Components to test.")`
			`*/`

			`#include "unity.h"`
			`#include "../include/BNO08xTestHelper.hpp"`

			`TEST_CASE("BNO08x Driver Creation for [MultiReportEnableDisable] Tests", "[MultiReportEnableDisable]")`
			`{`
			`const constexpr char* TEST_TAG = "BNO08x Driver Creation for [MultiReportEnableDisable] Tests";`
			`BNO08x* imu = nullptr;`

			`BNO08xTestHelper::print_test_start_banner(TEST_TAG);`

			`BNO08xTestHelper::print_test_msg(TEST_TAG, "Creating & initializing BNO08x driver.");`
			`BNO08xTestHelper::create_test_imu();`
			`imu = BNO08xTestHelper::get_test_imu();`

			`// ensure IMU initialized successfully`
			`TEST_ASSERT_EQUAL(true, imu->initialize());`
			`BNO08xTestHelper::print_test_end_banner(TEST_TAG);`
			`}`

			`TEST_CASE("Enable/Disable Dual Report", "[MultiReportEnableDisable]")`
			`{`
			`const constexpr char* TEST_TAG = "Enable/Disable Dual Report";`
			`static const constexpr uint8_t ENABLED_REPORT_COUNT = 2;`
			`static const constexpr uint8_t RX_REPORT_TRIAL_CNT = ENABLED_REPORT_COUNT * 5;`
			`static const constexpr uint32_t REPORT_PERIOD = 100000UL; // 100ms`

			`BNO08x* imu = nullptr;`
			`char msg_buff[200] = {};`
			`bool data_available = false;`
			`bool data_available_accel = false;`
			`bool data_available_lin_accel = false;`

			`bno08x_accel_t data;`

			`BNO08xTestHelper::print_test_start_banner(TEST_TAG);`

			`imu = BNO08xTestHelper::get_test_imu();`

			`TEST_ASSERT_EQUAL(true, imu->accelerometer.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.enable(REPORT_PERIOD));`

			`for (int i = 0; i < RX_REPORT_TRIAL_CNT; i++)`
			`{`
			`data_available = imu->data_available();`
			`TEST_ASSERT_EQUAL(true, data_available);`

			`if (imu->accelerometer.has_new_data())`
			`{`
			`data_available_accel = true;`
			`data = imu->accelerometer.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: Accel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data.x, data.y, data.z,`
			`BNO08x::accuracy_to_str(data.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->linear_accelerometer.has_new_data())`
			`{`
			`data_available_lin_accel = true;`
			`data = imu->linear_accelerometer.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: LinAccel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data.x, data.y, data.z,`
			`BNO08x::accuracy_to_str(data.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`
			`}`

			`TEST_ASSERT_EQUAL(true, imu->accelerometer.disable());`
			`TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.disable());`

			`TEST_ASSERT_EQUAL(true, data_available_accel);`
			`TEST_ASSERT_EQUAL(true, data_available_lin_accel);`

			`BNO08xTestHelper::print_test_end_banner(TEST_TAG);`
			`}`

			`TEST_CASE("Enable/Disable Quad Report", "[MultiReportEnableDisable]")`
			`{`
			`const constexpr char* TEST_TAG = "Enable/Disable Quad Report";`
			`static const constexpr uint8_t ENABLED_REPORT_COUNT = 4;`
			`static const constexpr uint8_t RX_REPORT_TRIAL_CNT = ENABLED_REPORT_COUNT * 5;`
			`static const constexpr uint32_t REPORT_PERIOD = 100000UL; // 100ms`

			`BNO08x* imu = nullptr;`
			`char msg_buff[200] = {};`
			`bool data_available = false;`
			`bool data_available_accel = false;`
			`bool data_available_lin_accel = false;`
			`bool data_available_gravity = false;`
			`bool data_available_cal_gyro = false;`

			`bno08x_accel_t data_accel;`
			`bno08x_gyro_t data_vel;`

			`BNO08xTestHelper::print_test_start_banner(TEST_TAG);`

			`imu = BNO08xTestHelper::get_test_imu();`

			`TEST_ASSERT_EQUAL(true, imu->accelerometer.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->gravity.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->cal_gyro.enable(REPORT_PERIOD));`

			`for (int i = 0; i < RX_REPORT_TRIAL_CNT; i++)`
			`{`
			`data_available = imu->data_available();`
			`TEST_ASSERT_EQUAL(true, data_available);`

			`if (imu->accelerometer.has_new_data())`
			`{`
			`data_available_accel = true;`
			`data_accel = imu->accelerometer.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: Accel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,`
			`data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->linear_accelerometer.has_new_data())`
			`{`
			`data_available_lin_accel = true;`
			`data_accel = imu->linear_accelerometer.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: LinAccel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x,`
			`data_accel.y, data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->gravity.has_new_data())`
			`{`
			`data_available_gravity = true;`
			`data_accel = imu->gravity.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: Gravity: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,`
			`data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->cal_gyro.has_new_data())`
			`{`
			`data_available_cal_gyro = true;`
			`data_vel = imu->cal_gyro.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: CalGyro: [rad/s] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_vel.x, data_vel.y,`
			`data_vel.z, BNO08x::accuracy_to_str(data_vel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`
			`}`

			`TEST_ASSERT_EQUAL(true, imu->accelerometer.disable());`
			`TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.disable());`
			`TEST_ASSERT_EQUAL(true, imu->gravity.disable());`
			`TEST_ASSERT_EQUAL(true, imu->cal_gyro.disable());`

			`TEST_ASSERT_EQUAL(true, data_available_accel);`
			`TEST_ASSERT_EQUAL(true, data_available_lin_accel);`
			`TEST_ASSERT_EQUAL(true, data_available_gravity);`
			`TEST_ASSERT_EQUAL(true, data_available_cal_gyro);`

			`BNO08xTestHelper::print_test_end_banner(TEST_TAG);`
			`}`

			`TEST_CASE("Enable/Disable Octo Report", "[MultiReportEnableDisable]")`
			`{`
			`const constexpr char* TEST_TAG = "Enable/Disable Octo Report";`
			`static const constexpr uint8_t ENABLED_REPORT_COUNT = 8;`
			`static const constexpr uint8_t RX_REPORT_TRIAL_CNT = ENABLED_REPORT_COUNT * 5;`
			`static const constexpr uint32_t REPORT_PERIOD = 100000UL; // 100ms`

			`BNO08x* imu = nullptr;`
			`char msg_buff[200] = {};`
			`bool data_available = false;`
			`bool data_available_accel = false;`
			`bool data_available_lin_accel = false;`
			`bool data_available_gravity = false;`
			`bool data_available_cal_gyro = false;`
			`bool data_available_cal_magnetometer = false;`
			`bool data_available_rv = false;`
			`bool data_available_rv_game = false;`
			`bool data_available_rv_geomagnetic = false;`

			`bno08x_accel_t data_accel;`
			`bno08x_gyro_t data_vel;`
			`bno08x_magf_t data_magf;`
			`bno08x_quat_t data_quat;`

			`BNO08xTestHelper::print_test_start_banner(TEST_TAG);`

			`imu = BNO08xTestHelper::get_test_imu();`

			`TEST_ASSERT_EQUAL(true, imu->accelerometer.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->gravity.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->cal_gyro.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->cal_magnetometer.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->rv.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->rv_game.enable(REPORT_PERIOD));`
			`TEST_ASSERT_EQUAL(true, imu->rv_geomagnetic.enable(REPORT_PERIOD));`

			`for (int i = 0; i < RX_REPORT_TRIAL_CNT; i++)`
			`{`
			`data_available = imu->data_available();`
			`TEST_ASSERT_EQUAL(true, data_available);`

			`if (imu->accelerometer.has_new_data())`
			`{`
			`data_available_accel = true;`
			`data_accel = imu->accelerometer.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: Accel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,`
			`data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->linear_accelerometer.has_new_data())`
			`{`
			`data_available_lin_accel = true;`
			`data_accel = imu->linear_accelerometer.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: LinAccel: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x,`
			`data_accel.y, data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->gravity.has_new_data())`
			`{`
			`data_available_gravity = true;`
			`data_accel = imu->gravity.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: Gravity: [m/s^2] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_accel.x, data_accel.y,`
			`data_accel.z, BNO08x::accuracy_to_str(data_accel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->cal_gyro.has_new_data())`
			`{`
			`data_available_cal_gyro = true;`
			`data_vel = imu->cal_gyro.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: CalGyro: [rad/s] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_vel.x, data_vel.y,`
			`data_vel.z, BNO08x::accuracy_to_str(data_vel.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->cal_magnetometer.has_new_data())`
			`{`
			`data_available_cal_magnetometer = true;`
			`data_magf = imu->cal_magnetometer.get();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: CalMagnetometer: [uTesla] x: %.2f y: %.2f z: %.2f accuracy: %s ", (i + 1), data_magf.x,`
			`data_magf.y, data_magf.z, BNO08x::accuracy_to_str(data_magf.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->rv.has_new_data())`
			`{`
			`data_available_rv = true;`
			`data_quat = imu->rv.get_quat();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: RV: [n/a] real: %.2f i: %.2f j: %.2f k: %.2f accuracy: %s ", (i + 1), data_quat.real,`
			`data_quat.i, data_quat.j, data_quat.k, BNO08x::accuracy_to_str(data_quat.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->rv_game.has_new_data())`
			`{`
			`data_available_rv_game = true;`
			`data_quat = imu->rv_game.get_quat();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: RV Game: [n/a] real: %.2f i: %.2f j: %.2f k: %.2f accuracy: %s ", (i + 1), data_quat.real,`
			`data_quat.i, data_quat.j, data_quat.k, BNO08x::accuracy_to_str(data_quat.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`

			`if (imu->rv_geomagnetic.has_new_data())`
			`{`
			`data_available_rv_geomagnetic = true;`
			`data_quat = imu->rv_geomagnetic.get_quat();`
			`sprintf(msg_buff, "Rx Data Trial %d Success: RV Geomagnetic: [n/a] real: %.2f i: %.2f j: %.2f k: %.2f accuracy: %s ", (i + 1),`
			`data_quat.real, data_quat.i, data_quat.j, data_quat.k, BNO08x::accuracy_to_str(data_quat.accuracy));`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, msg_buff);`
			`}`
			`}`

			`TEST_ASSERT_EQUAL(true, imu->accelerometer.disable());`
			`TEST_ASSERT_EQUAL(true, imu->linear_accelerometer.disable());`
			`TEST_ASSERT_EQUAL(true, imu->gravity.disable());`
			`TEST_ASSERT_EQUAL(true, imu->cal_gyro.disable());`
			`TEST_ASSERT_EQUAL(true, imu->cal_magnetometer.disable());`
			`TEST_ASSERT_EQUAL(true, imu->rv.disable());`
			`TEST_ASSERT_EQUAL(true, imu->rv_game.disable());`
			`TEST_ASSERT_EQUAL(true, imu->rv_geomagnetic.disable());`

			`TEST_ASSERT_EQUAL(true, data_available_accel);`
			`TEST_ASSERT_EQUAL(true, data_available_lin_accel);`
			`TEST_ASSERT_EQUAL(true, data_available_gravity);`
			`TEST_ASSERT_EQUAL(true, data_available_cal_gyro);`
			`TEST_ASSERT_EQUAL(true, data_available_cal_magnetometer);`
			`TEST_ASSERT_EQUAL(true, data_available_rv);`
			`TEST_ASSERT_EQUAL(true, data_available_rv_game);`
			`TEST_ASSERT_EQUAL(true, data_available_rv_geomagnetic);`

			`BNO08xTestHelper::print_test_end_banner(TEST_TAG);`
			`}`

			`TEST_CASE("BNO08x Driver Cleanup for [MultiReportEnableDisable] Tests", "[MultiReportEnableDisable]")`
			`{`
			`const constexpr char* TEST_TAG = "BNO08x Driver Cleanup for [MultiReportEnableDisable] Tests";`

			`BNO08xTestHelper::print_test_start_banner(TEST_TAG);`
			`BNO08xTestHelper::print_test_msg(TEST_TAG, "Destroying BNO08x Driver.");`

			`BNO08xTestHelper::destroy_test_imu();`
			`BNO08xTestHelper::print_test_end_banner(TEST_TAG);`
			`}`