relay_chn/test_apps/main/test_relay_chn.c

#include "driver/gpio.h"
#include "unity.h"
#include "unity_test_utils.h"
#include "relay_chn.h" // Main header file for the relay_chn component
#include <esp_log.h>
#include <freertos/FreeRTOS.h>
#include <freertos/task.h>
#include "sdkconfig.h" // For accessing CONFIG_* values
#include <string.h>


const char *TAG = "RELAY_CHN_TEST";

// Test GPIOs and channel IDs
// Please ensure these GPIOs are correct and suitable for your board.
// Two channels (4 GPIOs) are used as an example.
const gpio_num_t gpio_map[] = {GPIO_NUM_4, GPIO_NUM_5, GPIO_NUM_18, GPIO_NUM_19};
const uint8_t gpio_count = sizeof(gpio_map) / sizeof(gpio_map[0]);
// Assuming 2 GPIOs are used per channel
const uint8_t relay_chn_count = gpio_count / 2; 

const uint32_t opposite_inertia_ms = CONFIG_RELAY_CHN_OPPOSITE_INERTIA_MS;

// Tolerant delay margin to ensure operations complete, especially after inertia.
const uint32_t test_delay_margin_ms = 50; 

static bool g_is_component_initialized = false;

// --- Test Setup/Teardown Functions ---
void setUp(void) {
    // Reset state before each test. Initialization is now done inside each test case
    // to allow for testing of initialization failures.
    g_is_component_initialized = false;
}

void tearDown(void) {
    // Conditionally destroy the component to avoid crashing if creation failed.
    if (g_is_component_initialized) {
        relay_chn_destroy();
    }
}


// --- Initialization Tests ---

TEST_CASE("relay_chn_create handles invalid arguments", "[relay_chn][init]")
{
    // 1. Test with NULL gpio_map
    TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, relay_chn_create(NULL, gpio_count));

    // 2. Test with incorrect gpio_count (must be RELAY_CHN_COUNT * 2)
    TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, relay_chn_create(gpio_map, gpio_count - 1));
    TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, relay_chn_create(gpio_map, 1));
    TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, relay_chn_create(gpio_map, 0));

    // 3. Test with invalid GPIO numbers (GPIO_NUM_MAX is an invalid GPIO for output)
    gpio_num_t invalid_gpio_map[] = {GPIO_NUM_4, GPIO_NUM_MAX, GPIO_NUM_18, GPIO_NUM_19};
    TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, relay_chn_create(invalid_gpio_map, gpio_count));
}

// --- Basic Functionality Tests ---

// TEST_CASE: Test that relay channels initialize correctly to RELAY_CHN_STATE_FREE
TEST_CASE("Relay channels initialize correctly to FREE state", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(i));
    }
}

// TEST_CASE: Test that relays do nothing when an invlid channel id given
TEST_CASE("Run forward does nothing if channel id is invalid", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        int invalid_id = relay_chn_count * 2 + i;
        relay_chn_run_forward(invalid_id); // relay_chn_run_forward returns void
        // Short delay for state to update
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(i));
    }
}

// TEST_CASE: Test that relays run in the forward direction and update their state
TEST_CASE("Relay channels run forward and update state", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        relay_chn_run_forward(i); // relay_chn_run_forward returns void
        // Short delay for state to update
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(i));
    }
}

// TEST_CASE: Test that relays do nothing when an invlid channel id given
TEST_CASE("Run reverse does nothing if channel id is invalid", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Verify that no valid channels were affected
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        int invalid_id = relay_chn_count * 2 + i;
        // Call run_reverse with an invalid ID
        relay_chn_run_reverse(invalid_id);
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(i));
    }
}

// TEST_CASE: Test that relays run in the reverse direction and update their state
TEST_CASE("Relay channels run reverse and update state", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        relay_chn_run_reverse(i); // relay_chn_run_reverse returns void
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(i));
    }
}


// ### Broadcast Command (RELAY_CHN_ID_ALL) Tests

TEST_CASE("run_forward with ID_ALL sets all channels to FORWARD", "[relay_chn][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    relay_chn_run_forward(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(i));
    }
}

TEST_CASE("run_reverse with ID_ALL sets all channels to REVERSE", "[relay_chn][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    relay_chn_run_reverse(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(i));
    }
}

TEST_CASE("stop with ID_ALL stops all running channels", "[relay_chn][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Start all channels forward to ensure they are in a known running state
    relay_chn_run_forward(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));

    // 2. Stop all channels using the broadcast command
    relay_chn_stop(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));

    // 3. Verify all channels have transitioned to the FREE state
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(i));
    }
}



// TEST_CASE: Test that relays stop and transition to RELAY_CHN_STATE_FREE
// This test also verifies the transition to FREE state after a STOP command.
TEST_CASE("Relay channels stop and update to FREE state", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        // First, run forward to test stopping and transitioning to FREE state
        relay_chn_run_forward(i); // relay_chn_run_forward returns void
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(i));

        // Now, issue the stop command
        relay_chn_stop(i); // relay_chn_stop returns void
        // Immediately after stop, state should be STOPPED
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_STOPPED, relay_chn_get_state(i));

        // Then, wait for the inertia period for it to transition to RELAY_CHN_STATE_FREE
        vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(i));
    }
}

// TEST_CASE: Get state should return UNDEFINED when id is not valid
TEST_CASE("Get state returns UNDEFINED when id is invalid", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        int invalid_id = relay_chn_count * 2 + i;
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_UNDEFINED, relay_chn_get_state(invalid_id));
    }
    // Test for running states also
    relay_chn_run_forward(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        int invalid_id = relay_chn_count * 2 + i;
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_UNDEFINED, relay_chn_get_state(invalid_id));
    }
}

// TEST_CASE: Get state string should return "UNKNOWN" when id is not valid
TEST_CASE("Get state string returns UNKNOWN when id is invalid", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    for (uint8_t i = 0; i < relay_chn_count; i++) {
        int invalid_id = relay_chn_count * 2 + i;
        TEST_ASSERT_EQUAL_STRING("UNKNOWN", relay_chn_get_state_str(invalid_id));
    }
    // Test for running states also
    relay_chn_run_forward(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        int invalid_id = relay_chn_count * 2 + i;
        TEST_ASSERT_EQUAL_STRING("UNKNOWN", relay_chn_get_state_str(invalid_id));
    }
}

// TEST_CASE: Test independent operation of multiple relay channels
TEST_CASE("Multiple channels can operate independently", "[relay_chn]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    if (relay_chn_count >= 2) {
        // Start Channel 0 in forward direction
        relay_chn_run_forward(0); // relay_chn_run_forward returns void
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(0));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(1)); // Other channel should not be affected

        // Start Channel 1 in reverse direction
        relay_chn_run_reverse(1); // relay_chn_run_reverse returns void
        vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(0));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(1));

        // Stop Channel 0 and wait for it to become FREE
        relay_chn_stop(0); // relay_chn_stop returns void
        vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(0));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(1)); // Other channel should continue running

        // Stop Channel 1 and wait for it to become FREE
        relay_chn_stop(1); // relay_chn_stop returns void
        vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(0));
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(1));
    } else {
        ESP_LOGW("TEST", "Skipping 'Multiple channels can operate independently' test: Not enough channels available.");
    }
}


// ### Inertia and State Transition Tests

// This section specifically targets the inertia periods and complex state transitions as per the component's logic.

// TEST_CASE: Test transition from forward to reverse with inertia and state checks
// Scenario: RELAY_CHN_STATE_FORWARD -> (relay_chn_run_reverse) -> RELAY_CHN_STATE_STOPPED -> (inertia) -> RELAY_CHN_STATE_REVERSE
TEST_CASE("Forward to Reverse transition with opposite inertia", "[relay_chn][inertia]") {
    uint8_t ch = 0; // Channel to test

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Start in forward direction
    relay_chn_run_forward(ch); // relay_chn_run_forward returns void
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); // Short delay for state stabilization
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));

    // 2. Issue reverse command
    relay_chn_run_reverse(ch); // relay_chn_run_reverse returns void
    // Immediately after the command, the motor should be stopped
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); 
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE_PENDING, relay_chn_get_state(ch)); 

    // Wait for the inertia period (after which the reverse command will be dispatched)
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms)); 
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(ch)); // Should now be in reverse state
}

// TEST_CASE: Test transition from reverse to forward with inertia and state checks
// Scenario: RELAY_CHN_STATE_REVERSE -> (relay_chn_run_forward) -> RELAY_CHN_STATE_STOPPED -> (inertia) -> RELAY_CHN_STATE_FORWARD
TEST_CASE("Reverse to Forward transition with opposite inertia", "[relay_chn][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Start in reverse direction
    relay_chn_run_reverse(ch); // relay_chn_run_reverse returns void
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(ch));

    // 2. Issue forward command
    relay_chn_run_forward(ch); // relay_chn_run_forward returns void
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD_PENDING, relay_chn_get_state(ch));

    // Wait for inertia
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));
}

// TEST_CASE: Test issuing the same run command while already running (no inertia expected)
// Scenario: RELAY_CHN_STATE_FORWARD -> (relay_chn_run_forward) -> RELAY_CHN_STATE_FORWARD
TEST_CASE("Running in same direction does not incur inertia", "[relay_chn][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Start in forward direction
    relay_chn_run_forward(ch); // relay_chn_run_forward returns void
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));

    // 2. Issue the same forward command again
    relay_chn_run_forward(ch); // relay_chn_run_forward returns void
    // As per the code, is_direction_opposite_to_current_motion should return false, so no inertia.
    // Just a short delay to check state remains the same.
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); 
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));
}

// TEST_CASE: Test transition from FREE state to running (no inertia expected)
// Scenario: RELAY_CHN_STATE_FREE -> (relay_chn_run_forward) -> RELAY_CHN_STATE_FORWARD
TEST_CASE("FREE to Running transition without inertia", "[relay_chn][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // setUp() should have already brought the channel to FREE state
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(ch));

    // Start in forward direction
    relay_chn_run_forward(ch); // relay_chn_run_forward returns void
    // No inertia is expected when starting from FREE state.
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));
}

// --- Listener Test Globals ---
typedef struct {
    uint8_t chn_id;
    relay_chn_state_t old_state;
    relay_chn_state_t new_state;
    int call_count;
} listener_callback_info_t;

static listener_callback_info_t listener1_info;
static listener_callback_info_t listener2_info;

// --- Listener Test Helper Functions ---

// Clear the memory from possible garbage values
static void reset_listener_info(listener_callback_info_t* info) {
    memset(info, 0, sizeof(listener_callback_info_t));
}

static void test_listener_1(uint8_t chn_id, relay_chn_state_t old_state, relay_chn_state_t new_state) {
    listener1_info.chn_id = chn_id;
    listener1_info.old_state = old_state;
    listener1_info.new_state = new_state;
    listener1_info.call_count++;
}

static void test_listener_2(uint8_t chn_id, relay_chn_state_t old_state, relay_chn_state_t new_state) {
    listener2_info.chn_id = chn_id;
    listener2_info.old_state = old_state;
    listener2_info.new_state = new_state;
    listener2_info.call_count++;
}

// ### Listener Functionality Tests

TEST_CASE("Listener is called on state change", "[relay_chn][listener]") {
    uint8_t ch = 0;
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    reset_listener_info(&listener1_info);

    // 1. Register the listener
    TEST_ESP_OK(relay_chn_register_listener(test_listener_1));

    // 2. Trigger a state change
    relay_chn_run_forward(ch);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); // Allow event to be processed

    // 3. Verify the listener was called with correct parameters
    TEST_ASSERT_EQUAL(1, listener1_info.call_count);
    TEST_ASSERT_EQUAL(ch, listener1_info.chn_id);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, listener1_info.old_state);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, listener1_info.new_state);

    // 4. Unregister to clean up
    relay_chn_unregister_listener(test_listener_1);
}

TEST_CASE("Unregistered listener is not called", "[relay_chn][listener]") {
    uint8_t ch = 0;
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    reset_listener_info(&listener1_info);

    // 1. Register and then immediately unregister the listener
    TEST_ESP_OK(relay_chn_register_listener(test_listener_1));
    relay_chn_unregister_listener(test_listener_1);

    // 2. Trigger a state change
    relay_chn_run_forward(ch);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));

    // 3. Verify the listener was NOT called
    TEST_ASSERT_EQUAL(0, listener1_info.call_count);
}

TEST_CASE("Multiple listeners are called on state change", "[relay_chn][listener]") {
    uint8_t ch = 0;
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    reset_listener_info(&listener1_info);
    reset_listener_info(&listener2_info);

    // 1. Register two different listeners
    TEST_ESP_OK(relay_chn_register_listener(test_listener_1));
    TEST_ESP_OK(relay_chn_register_listener(test_listener_2));

    // 2. Trigger a state change
    relay_chn_run_forward(ch);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));

    // 3. Verify listener 1 was called correctly
    TEST_ASSERT_EQUAL(1, listener1_info.call_count);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, listener1_info.old_state);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, listener1_info.new_state);

    // 4. Verify listener 2 was also called correctly
    TEST_ASSERT_EQUAL(1, listener2_info.call_count);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, listener2_info.old_state);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, listener2_info.new_state);

    // 5. Clean up
    relay_chn_unregister_listener(test_listener_1);
    relay_chn_unregister_listener(test_listener_2);
}

TEST_CASE("Listener registration handles invalid arguments and duplicates", "[relay_chn][listener]") {
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    reset_listener_info(&listener1_info);

    // 1. Registering a NULL listener should fail
    TEST_ASSERT_EQUAL(ESP_ERR_INVALID_ARG, relay_chn_register_listener(NULL));

    // 2. Unregistering a NULL listener should not crash
    relay_chn_unregister_listener(NULL);

    // 3. Registering the same listener twice should be handled gracefully
    TEST_ESP_OK(relay_chn_register_listener(test_listener_1));
    TEST_ESP_OK(relay_chn_register_listener(test_listener_1)); // Second call should be a no-op

    // 4. Trigger a state change and verify the listener is only called ONCE
    relay_chn_run_forward(0);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(1, listener1_info.call_count);

    // 5. Clean up
    relay_chn_unregister_listener(test_listener_1);
}


// ### Tilt Functionality Tests (Conditional)

// This section will only be compiled if **`CONFIG_RELAY_CHN_ENABLE_TILTING`** is defined as **`1`** in `sdkconfig`.

#if CONFIG_RELAY_CHN_ENABLE_TILTING == 1

#define RELAY_CHN_CMD_FORWARD 1
#define RELAY_CHN_CMD_REVERSE 2

// Helper function to prepare channel for tilt tests
void prepare_channel_for_tilt(uint8_t chn_id, int initial_cmd) {
    // Ensure the channel has had a 'last_run_cmd'
    if (initial_cmd == RELAY_CHN_CMD_FORWARD) {
        relay_chn_run_forward(chn_id);
    } else { // Assuming initial_cmd is RELAY_CHN_CMD_REVERSE
        relay_chn_run_reverse(chn_id);
    }
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); // Allow command to process
    relay_chn_stop(chn_id); // Stop it to set last_run_cmd but return to FREE for next test
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(chn_id));
}

// TEST_CASE: Test transition from running forward to tilt forward
// Scenario: RELAY_CHN_STATE_FORWARD -> (relay_chn_tilt_forward) -> RELAY_CHN_STATE_STOPPED -> (inertia) -> RELAY_CHN_STATE_TILT_FORWARD
TEST_CASE("Run Forward to Tilt Forward transition with inertia", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running forward first to set last_run_cmd
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_FORWARD);

    // 1. Start in forward direction
    relay_chn_run_forward(ch); 
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));

    // 2. Issue tilt forward command
    relay_chn_tilt_forward(ch); 
    // After tilt command, it should immediately stop and then trigger inertia.
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); 
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_STOPPED, relay_chn_get_state(ch)); 

    // Wait for the inertia period (after which the tilt command will be dispatched)
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_FORWARD, relay_chn_get_state(ch));
}

// TEST_CASE: Test transition from running reverse to tilt reverse
// Scenario: RELAY_CHN_STATE_REVERSE -> (relay_chn_tilt_reverse) -> RELAY_CHN_STATE_STOPPED -> (inertia) -> RELAY_CHN_STATE_TILT_REVERSE
TEST_CASE("Run Reverse to Tilt Reverse transition with inertia", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running reverse first to set last_run_cmd
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_REVERSE);

    // 1. Start in reverse direction
    relay_chn_run_reverse(ch); 
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(ch));

    // 2. Issue tilt reverse command
    relay_chn_tilt_reverse(ch); 
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_STOPPED, relay_chn_get_state(ch));

    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_REVERSE, relay_chn_get_state(ch));
}

// TEST_CASE: Test transition from FREE state to tilt forward (now with preparation)
// Scenario: RELAY_CHN_STATE_FREE -> (prepare) -> RELAY_CHN_STATE_FREE -> (relay_chn_tilt_forward) -> RELAY_CHN_STATE_STOPPED -> (inertia) -> RELAY_CHN_STATE_TILT_FORWARD
TEST_CASE("FREE to Tilt Forward transition with inertia (prepared)", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running forward first to set last_run_cmd
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_FORWARD);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(ch)); // Ensure we are back to FREE

    // Issue tilt forward command
    relay_chn_tilt_forward(ch); 
    // From FREE state, tilt command should still incur the inertia due to the internal timer logic
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); 
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_FORWARD, relay_chn_get_state(ch));
}

// TEST_CASE: Test transition from FREE state to tilt reverse (now with preparation)
// Scenario: RELAY_CHN_STATE_FREE -> (prepare) -> RELAY_CHN_STATE_FREE -> (relay_chn_tilt_reverse) -> RELAY_CHN_STATE_STOPPED -> (inertia) -> RELAY_CHN_STATE_TILT_REVERSE
TEST_CASE("FREE to Tilt Reverse transition with inertia (prepared)", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running reverse first to set last_run_cmd
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_REVERSE);
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(ch)); // Ensure we are back to FREE

    // Issue tilt reverse command
    relay_chn_tilt_reverse(ch); 
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_REVERSE, relay_chn_get_state(ch));
}

// TEST_CASE: Test transition from tilt forward to run forward (inertia expected for run)
// Scenario: RELAY_CHN_STATE_TILT_FORWARD -> (relay_chn_run_forward) -> RELAY_CHN_STATE_FORWARD
TEST_CASE("Tilt Forward to Run Forward transition with inertia", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running forward first to set last_run_cmd, then tilt
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_FORWARD);
    relay_chn_tilt_forward(ch); // Go to tilt state
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_FORWARD, relay_chn_get_state(ch));

    // 2. Issue run forward command
    relay_chn_run_forward(ch); 
    // From Tilt to Run in the same logical name but in the opposite direction, inertia is expected.
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD_PENDING, relay_chn_get_state(ch));
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));
}

// TEST_CASE: Test transition from tilt reverse to run reverse (no inertia expected for run)
// Scenario: RELAY_CHN_STATE_TILT_REVERSE -> (relay_chn_run_reverse) -> RELAY_CHN_STATE_REVERSE
TEST_CASE("Tilt Reverse to Run Reverse transition with inertia", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running reverse first to set last_run_cmd, then tilt
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_REVERSE);
    relay_chn_tilt_reverse(ch); // Go to tilt state
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_REVERSE, relay_chn_get_state(ch));

    // 2. Issue run reverse command
    relay_chn_run_reverse(ch); 
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE_PENDING, relay_chn_get_state(ch));
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(ch));
}

// TEST_CASE: Test transition from tilt forward to run reverse (without inertia)
// Scenario: RELAY_CHN_STATE_TILT_FORWARD -> (relay_chn_run_reverse) -> RELAY_CHN_STATE_REVERSE
TEST_CASE("Tilt Forward to Run Reverse transition without inertia", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running forward first to set last_run_cmd, then tilt
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_FORWARD);
    relay_chn_tilt_forward(ch); // Go to tilt state
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_FORWARD, relay_chn_get_state(ch));

    // 2. Issue run reverse command (opposite direction)
    relay_chn_run_reverse(ch); 
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_REVERSE, relay_chn_get_state(ch));
}

// TEST_CASE: Test stopping from a tilt state (no inertia for stop command itself)
// Scenario: RELAY_CHN_STATE_TILT_FORWARD -> (relay_chn_stop) -> RELAY_CHN_STATE_STOPPED -> (inertia) -> RELAY_CHN_STATE_FREE
TEST_CASE("Tilt to Stop transition without immediate inertia for stop", "[relay_chn][tilt][inertia]") {
    uint8_t ch = 0;

    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // Prepare channel by running forward first to set last_run_cmd, then tilt
    prepare_channel_for_tilt(ch, RELAY_CHN_CMD_FORWARD);
    relay_chn_tilt_forward(ch); // Go to tilt state
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_FORWARD, relay_chn_get_state(ch));

    // 2. Issue stop command
    relay_chn_stop(ch);
    // Stop command should apply immediately, setting state to FREE since last state was tilt.
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(ch));
}

// ### Tilt Broadcast Command (RELAY_CHN_ID_ALL) Tests

TEST_CASE("tilt_forward with ID_ALL sets all channels to TILT_FORWARD", "[relay_chn][tilt][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Prepare all channels.
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        prepare_channel_for_tilt(i, RELAY_CHN_CMD_FORWARD);
    }

    // 2. Issue tilt forward to all channels
    relay_chn_tilt_forward(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); // Tilt from FREE doesn't have stop-inertia

    // 3. Verify all channels are tilting forward
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_FORWARD, relay_chn_get_state(i));
    }
}

TEST_CASE("tilt_reverse with ID_ALL sets all channels to TILT_REVERSE", "[relay_chn][tilt][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Prepare all channels.
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        prepare_channel_for_tilt(i, RELAY_CHN_CMD_REVERSE);
    }

    // 2. Issue tilt reverse to all channels
    relay_chn_tilt_reverse(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));

    // 3. Verify all channels are tilting reverse
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_REVERSE, relay_chn_get_state(i));
    }
}

TEST_CASE("tilt_stop with ID_ALL stops all tilting channels", "[relay_chn][tilt][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Prepare and start all channels tilting forward
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        prepare_channel_for_tilt(i, RELAY_CHN_CMD_REVERSE);
    }
    relay_chn_tilt_forward(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));

    // 2. Stop tilting on all channels
    relay_chn_tilt_stop(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));

    // 3. Verify all channels are free
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(i));
    }
}

TEST_CASE("tilt_auto with ID_ALL tilts channels based on last run direction", "[relay_chn][tilt][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // This test requires at least 2 channels to demonstrate different behaviors
    TEST_ASSERT_GREATER_OR_EQUAL_MESSAGE(2, relay_chn_count, "Test requires at least 2 channels");

    // 1. Prepare channel 0 with last run FORWARD and channel 1 with last run REVERSE
    prepare_channel_for_tilt(0, RELAY_CHN_CMD_FORWARD);
    prepare_channel_for_tilt(1, RELAY_CHN_CMD_REVERSE);

    // 2. Issue auto tilt command to all channels
    relay_chn_tilt_auto(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); // Tilt from FREE state is dispatched immediately

    // 3. Verify channel 0 tilts forward (last run was forward) and channel 1 tilts reverse (last run was reverse)
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_FORWARD, relay_chn_get_state(0));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_TILT_REVERSE, relay_chn_get_state(1));
}

#else // CONFIG_RELAY_CHN_ENABLE_TILTING == 0
// If tilt functionality is disabled, these tests are skipped.
// A dummy test case is added to indicate this in the test output.
TEST_CASE("Tilt functionality is disabled, skipping tilt tests", "[relay_chn][tilt_disabled]") {
    TEST_ASSERT_TRUE(true); // Just to ensure at least one test passes for visibility
}
#endif // CONFIG_RELAY_CHN_ENABLE_TILTING


// ### Direction Flipping Tests

TEST_CASE("Single channel direction can be flipped", "[relay_chn][direction]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;
    const uint8_t ch = 0;

    // 1. Initial direction should be default
    TEST_ASSERT_EQUAL(RELAY_CHN_DIRECTION_DEFAULT, relay_chn_get_direction(ch));

    // 2. Flip the direction
    relay_chn_flip_direction(ch);
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms)); // Wait for flip inertia

    // 3. Verify direction is flipped
    TEST_ASSERT_EQUAL(RELAY_CHN_DIRECTION_FLIPPED, relay_chn_get_direction(ch));

    // 4. Flip back
    relay_chn_flip_direction(ch);
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms)); // Wait for flip inertia

    // 5. Verify direction is back to default
    TEST_ASSERT_EQUAL(RELAY_CHN_DIRECTION_DEFAULT, relay_chn_get_direction(ch));
}

TEST_CASE("All channels direction can be flipped simultaneously", "[relay_chn][direction][all]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;

    // 1. Flip all channels
    relay_chn_flip_direction(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));

    // 2. Verify all channels are flipped
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_DIRECTION_FLIPPED, relay_chn_get_direction(i));
    }

    // 3. Flip all back
    relay_chn_flip_direction(RELAY_CHN_ID_ALL);
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));

    // 4. Verify all channels are back to default
    for (uint8_t i = 0; i < relay_chn_count; i++) {
        TEST_ASSERT_EQUAL(RELAY_CHN_DIRECTION_DEFAULT, relay_chn_get_direction(i));
    }
}

TEST_CASE("Flipping a running channel stops it and flips direction", "[relay_chn][direction]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;
    const uint8_t ch = 0;

    // 1. Start channel running and verify state
    relay_chn_run_forward(ch);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FORWARD, relay_chn_get_state(ch));

    // 2. Flip the direction while running
    relay_chn_flip_direction(ch);
    vTaskDelay(pdMS_TO_TICKS(test_delay_margin_ms)); // Give time for events to process
    
    // 3. The channel should stop as part of the flip process
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_STOPPED, relay_chn_get_state(ch));

    // 4. Wait for the flip inertia to pass, after which it should be FREE and FLIPPED
    vTaskDelay(pdMS_TO_TICKS(opposite_inertia_ms + test_delay_margin_ms));
    TEST_ASSERT_EQUAL(RELAY_CHN_STATE_FREE, relay_chn_get_state(ch));
    TEST_ASSERT_EQUAL(RELAY_CHN_DIRECTION_FLIPPED, relay_chn_get_direction(ch));
}

TEST_CASE("Direction flip handles invalid channel ID gracefully", "[relay_chn][direction]")
{
    TEST_ESP_OK(relay_chn_create(gpio_map, gpio_count));
    g_is_component_initialized = true;
    const uint8_t invalid_ch = relay_chn_count + 5;

    relay_chn_flip_direction(invalid_ch); // Call with an invalid ID
    TEST_ASSERT_EQUAL(RELAY_CHN_DIRECTION_DEFAULT, relay_chn_get_direction(invalid_ch));
}


// ### `app_main` Function

// --- app_main function ---
void app_main(void) {
    // Run the Unity test runner
    unity_run_all_tests();

    ESP_LOGI(TAG, "============================== END OF TESTS ==============================");

    // After tests complete, instead of restarting, the device will halt.
    while (1) {
        vTaskDelay(pdMS_TO_TICKS(1000)); // Wait with low power consumption
    }
}