void mico_mfg_test(void)
{
char str[64];
char mac[6];
char *ssid;
sprintf(str, "Library Version: %s\r\n", system_lib_version());
mf_printf(str);
mf_printf("APP Version: ");
memset(str, 0, sizeof(str));
system_version(str, sizeof(str));
mf_printf(str);
mf_printf("\r\n");
memset(str, 0, sizeof(str));
wlan_driver_version(str, sizeof(str));
mf_printf("Driver: ");
mf_printf(str);
mf_printf("\r\n");
wlan_get_mac_address(mac);
sprintf(str, "MAC: %02X-%02X-%02X-%02X-%02X-%02X\r\n",
mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]);
mf_printf(str);
mfg_scan();
ssid = ssid_get();
mfg_connect(ssid);
mico_thread_sleep(MICO_NEVER_TIMEOUT);
}
/* mxchip library manufacture test. */
void mxchip_mfg_test(void)
{
char str[64];
char mac[6];
char *ssid;
mico_uart_config_t uart_config;
volatile ring_buffer_t rx_buffer;
volatile uint8_t * rx_data;
rx_data = malloc(50);
require(rx_data, exit);
/* Initialize UART interface */
uart_config.baud_rate = 115200;
uart_config.data_width = DATA_WIDTH_8BIT;
uart_config.parity = NO_PARITY;
uart_config.stop_bits = STOP_BITS_1;
uart_config.flow_control = FLOW_CONTROL_DISABLED;
uart_config.flags = UART_WAKEUP_DISABLE;
ring_buffer_init ( (ring_buffer_t *)&rx_buffer, (uint8_t *)rx_data, 50 );
MicoUartInitialize( MFG_TEST, &uart_config, (ring_buffer_t *)&rx_buffer );
mf_printf("==== MXCHIP Manufacture Test ====\r\n");
mf_printf("Bootloader Version: ");
mf_printf(mico_get_bootloader_ver());
mf_printf("\r\n");
sprintf(str, "Library Version: %s\r\n", system_lib_version());
mf_printf(str);
mf_printf("APP Version: ");
memset(str, 0, sizeof(str));
system_version(str, sizeof(str));
mf_printf(str);
mf_printf("\r\n");
memset(str, 0, sizeof(str));
MicoGetRfVer(str, sizeof(str));
mf_printf("Driver: ");
mf_printf(str);
mf_printf("\r\n");
wlan_get_mac_address(mac);
sprintf(str, "MAC: %02X-%02X-%02X-%02X-%02X-%02X\r\n",
mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]);
mf_printf(str);
mfg_scan();
ssid = ssid_get();
mfg_connect(ssid);
exit:
mico_thread_sleep(MICO_NEVER_TIMEOUT);
}
/**********************************************************
config cfg struct from otp
**********************************************************/
static void config_cfg_struct()
{
bool * flag = get_read_otp_flag();
if(false == (*flag)) {
wlan_set_mac_addr(get_wlan_mac_address());
} else {
int ret;
//get mac address
uint8_t mac[MLAN_MAC_ADDR_LENGTH];
wlan_get_mac_address((uint8_t *)mac);
memcpy(cfg_struct.mac_address,mac,MLAN_MAC_ADDR_LENGTH);
//get key & did,lengthof(key) + lengthof(did) = 24
uint8_t buffer[24];
ret = wlan_get_otp_user_data(buffer,24);
if(WM_SUCCESS == ret) {
//copy did & key to cfg_struct
memcpy(cfg_struct.device_id,buffer,sizeof(cfg_struct.device_id));
memcpy(cfg_struct.key,buffer+sizeof(cfg_struct.device_id),sizeof(buffer) - sizeof(cfg_struct.device_id));
} else {
LOG_ERROR("read otp fail \r\n");
pm_reboot_soc();
}
}
if(WM_SUCCESS != get_model_in_psm(cfg_struct.model,sizeof(cfg_struct.model))) {
//cfg_struct.url is useless now, define module only
strcpy(cfg_struct.model,DEFAULT_MODULE);
#if defined(CONFIG_CPU_MC200) && defined (CONFIG_WiFi_8801)
strcat(cfg_struct.model,"1");
#elif defined(CONFIG_CPU_MC200) && defined (CONFIG_WiFi_878x)
strcat(cfg_struct.model,"3");
#elif defined(CONFIG_CPU_MW300) && defined(MW300_68PIN)
strcat(cfg_struct.model,"4");
#elif defined(CONFIG_CPU_MW300)
strcat(cfg_struct.model,"2");
#endif
set_model_in_psm(cfg_struct.model);
}
}
static void test_wlan_get_mac_address(int argc, char **argv)
{
uint8_t mac[6];
wmprintf("MAC address\r\n");
if (wlan_get_mac_address(mac))
wmprintf("Error: unable to retrieve MAC address\r\n");
else
wmprintf("%02X:%02X:%02X:%02X:%02X:%02X\r\n",
mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]);
#ifdef CONFIG_P2P
wmprintf("P2P MAC address\r\n");
if (wlan_get_wfd_mac_address(mac))
wmprintf("Error: unable to retrieve P2P MAC address\r\n");
else
wmprintf("%02X:%02X:%02X:%02X:%02X:%02X\r\n",
mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]);
#endif
}
void micokit_ext_mfg_test(mico_Context_t *inContext)
{
OSStatus err = kUnknownErr;
char str[64] = {'\0'};
char mac[6];
int rgb_led_hue = 0;
uint8_t dht11_ret = 0;
uint8_t dht11_temp_data = 0;
uint8_t dht11_hum_data = 0;
int light_ret = 0;
uint16_t light_sensor_data = 0;
int infrared_ret = 0;
uint16_t infrared_reflective_data = 0;
int32_t bme280_temp = 0;
uint32_t bme280_hum = 0;
uint32_t bme280_press = 0;
UNUSED_PARAMETER(inContext);
mico_rtos_init_semaphore(&mfg_test_state_change_sem, 1);
err = MICOAddNotification( mico_notify_WIFI_SCAN_COMPLETED, (void *)mico_notify_WifiScanCompleteHandler );
require_noerr( err, exit );
while(1){
switch(mfg_test_module_number){
case 0: // mfg mode start
{
sprintf(str, "%s\r\nStart:\r\n%s\r\n%s", "TEST MODE", " next: Key2", " prev: Key1");
mf_printf(str);
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, MICO_WAIT_FOREVER));
break;
}
case 1: // OLED
{
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, 0))
{
sprintf(str, "%s OLED\r\n", OLED_MFG_TEST_PREFIX);
mf_printf(str);
mico_thread_msleep(300);
mf_printf(mfg_test_oled_test_string);
mico_thread_msleep(300);
}
OLED_Clear();
break;
}
case 2: // RGB_LED
{
sprintf(str, "%s RGB LED\r\nBlink: \r\n R=>G=>B", OLED_MFG_TEST_PREFIX);
mf_printf(str);
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, 0))
{
hsb2rgb_led_open(rgb_led_hue, 100, 50);
rgb_led_hue += 120;
if(rgb_led_hue >= 360){
rgb_led_hue = 0;
}
mico_thread_msleep(300);
}
hsb2rgb_led_open(0, 0, 0);
break;
}
case 3: // infrared sensor
{
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, 0))
{
infrared_ret = infrared_reflective_read(&infrared_reflective_data);
if(0 == infrared_ret){
sprintf(str, "%s Infrared\r\nInfrared: %d", OLED_MFG_TEST_PREFIX,
infrared_reflective_data);
mf_printf(str);
}
mico_thread_msleep(300);
}
break;
}
case 4: // DC Motor
{
sprintf(str, "%s DC Motor\r\nRun:\r\n on : 500ms\r\n off: 500ms", OLED_MFG_TEST_PREFIX);
mf_printf(str);
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, 0))
{
dc_motor_set(1);
mico_thread_msleep(500);
dc_motor_set(0);
mico_thread_msleep(500);
}
dc_motor_set(0);
break;
}
case 5: // BME280
{
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, 0))
{
err = bme280_sensor_init();
if(kNoErr != err){
sprintf(str, "%s BME280\r\nMoule not found!", OLED_MFG_TEST_PREFIX);
mf_printf(str);
// goto next mdoule
mico_thread_msleep(500);
mfg_test_module_number = (mfg_test_module_number+1)%(MFG_TEST_MAX_MODULE_NUM+1);
break;
}
else{
err = bme280_data_readout(&bme280_temp, &bme280_press, &bme280_hum);
if(kNoErr == err){
sprintf(str, "%s BME280\r\nT: %3.1fC\r\nH: %3.1f%%\r\nP: %5.2fkPa", OLED_MFG_TEST_PREFIX,
(float)bme280_temp/100, (float)bme280_hum/1024, (float)bme280_press/1000);
mf_printf(str);
}
else{
sprintf(str, "%s BME280\r\nRead error!", OLED_MFG_TEST_PREFIX);
mf_printf(str);
}
}
mico_thread_msleep(500);
}
break;
}
case 6: // DHT11
{
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, 0))
{
dht11_ret = DHT11_Read_Data(&dht11_temp_data, &dht11_hum_data);
if(0 == dht11_ret){
sprintf(str, "%s DHT11\r\nT: %3.1fC\r\nH: %3.1f%%", OLED_MFG_TEST_PREFIX,
(float)dht11_temp_data, (float)dht11_hum_data);
mf_printf(str);
}
mico_thread_sleep(1); // DHT11 must >= 1s
}
break;
}
case 7: // Light sensor
{
while(kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, 0))
{
light_ret = light_sensor_read(&light_sensor_data);
if(0 == light_ret){
sprintf(str, "%s Light\r\nLight: %d", OLED_MFG_TEST_PREFIX,
light_sensor_data);
mf_printf(str);
}
mico_thread_msleep(300);
}
break;
}
case 8: // wifi
{
wlan_get_mac_address(mac);
sprintf(str, "%s Wi-Fi\r\nMAC:\r\n %02X%02X%02X%02X%02X%02X", OLED_MFG_TEST_PREFIX,
mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]);
mf_printf(str);
//mico_thread_msleep(500);
scanap_done = false;
micoWlanStartScan();
while((!scanap_done) || (kNoErr != mico_rtos_get_semaphore(&mfg_test_state_change_sem, MICO_WAIT_FOREVER)));
break;
}
default:
goto exit; // error
break;
}
}
exit:
mico_thread_sleep(MICO_NEVER_TIMEOUT);
}
/* mxchip library manufacture test. */
void mxchip_mfg_test(void)
{
char str[128];
char mac[6];
char *ssid;
mico_uart_config_t uart_config;
volatile ring_buffer_t rx_buffer;
volatile uint8_t * rx_data;
mico_debug_enabled = 0;
rx_data = malloc(50);
require(rx_data, exit);
/* Initialize UART interface */
uart_config.baud_rate = 115200;
uart_config.data_width = DATA_WIDTH_8BIT;
uart_config.parity = NO_PARITY;
uart_config.stop_bits = STOP_BITS_1;
uart_config.flow_control = FLOW_CONTROL_DISABLED;
uart_config.flags = UART_WAKEUP_DISABLE;
ring_buffer_init ((ring_buffer_t *)&rx_buffer, (uint8_t *)rx_data, 50);
MicoUartInitialize (MFG_TEST, &uart_config, (ring_buffer_t *)&rx_buffer);
mf_printf ("==== MXCHIP Manufacture Test ====\r\n");
mf_printf ("Serial Number: ");
mf_printf (SERIAL_NUMBER);
mf_printf ("\r\n");
mf_printf ("App CRC: ");
memset (str, 0, sizeof (str));
app_crc (str, sizeof (str));
mf_printf (str);
mf_printf ("\r\n");
mf_printf ("Bootloader Version: ");
mf_printf (mico_get_bootloader_ver());
mf_printf ("\r\n");
sprintf (str, "Library Version: %s\r\n", system_lib_version());
mf_printf (str);
mf_printf ("APP Version: ");
memset (str, 0, sizeof (str));
system_version (str, sizeof (str));
mf_printf (str);
mf_printf ("\r\n");
memset (str, 0, sizeof (str));
wlan_driver_version (str, sizeof (str));
mf_printf ("Driver: ");
mf_printf (str);
mf_printf ("\r\n");
#ifdef MICO_BLUETOOTH_ENABLE
/* Initialise MICO SmartBridge */
mico_bt_init( MICO_BT_HCI_MODE, "SmartBridge Device", 0, 0 ); //Client + server connections
mico_bt_smartbridge_init( 0 );
mico_bt_dev_read_local_addr( (uint8_t *)mac );
sprintf( str, "Local Bluetooth Address: %02X-%02X-%02X-%02X-%02X-%02X\r\n", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5] );
mf_printf (str);
ble_scan();
#endif
wlan_get_mac_address (mac);
sprintf (str, "MAC: %02X-%02X-%02X-%02X-%02X-%02X\r\n",
mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]);
mf_printf(str);
mfg_scan();
if (test_for_app==0) {
ssid = ssid_get();
mfg_connect (ssid);
}
exit:
mico_thread_sleep(MICO_NEVER_TIMEOUT);
}
void mxchip_mfg_test(mico_Context_t *inContex)
{
char str[80];
char mac[6];
char *ssid;
UNUSED_PARAMETER(inContex);
mico_uart_config_t uart_config;
volatile ring_buffer_t rx_buffer;
volatile uint8_t * rx_data;
rx_data = malloc(100);
require(rx_data, exit);
/* Initialize UART interface */
uart_config.baud_rate = 115200;
uart_config.data_width = DATA_WIDTH_8BIT;
uart_config.parity = NO_PARITY;
uart_config.stop_bits = STOP_BITS_1;
uart_config.flow_control = FLOW_CONTROL_DISABLED;
uart_config.flags = UART_WAKEUP_DISABLE;
ring_buffer_init ( (ring_buffer_t *)&rx_buffer, (uint8_t *)rx_data, 100 );
MicoUartInitialize( MFG_TEST, &uart_config, (ring_buffer_t *)&rx_buffer );
sprintf(str, "Library Version: %s\r\n", system_lib_version());
mf_printf(str);
mf_printf("APP Version: ");
//memset(str, 0, sizeof(str));
//system_version(str, sizeof(str));
sprintf(str, "%s, build at %s %s, ", APP_INFO, __TIME__, __DATE__);
mf_printf(str);
sprintf(str, "%d.%d.%d",(u8)(ZC_MODULE_VERSION >> 16),(u8)(ZC_MODULE_VERSION >> 8),(u8)(ZC_MODULE_VERSION));
mf_printf(str);
mf_printf("\r\n");
mf_printf("Uart Info: ");
//memset(str, 0, sizeof(str));
//system_version(str, sizeof(str));
mf_printf(UART_INFO);
mf_printf("\r\n");
mf_printf("Server Info: ");
//memset(str, 0, sizeof(str));
//system_version(str, sizeof(str));
mf_printf(ADDR_INFO);
mf_printf("\r\n");
memset(str, 0, sizeof(str));
wlan_driver_version(str, sizeof(str));
mf_printf("Driver: ");
mf_printf(str);
mf_printf("\r\n");
wlan_get_mac_address(mac);
sprintf(str, "MAC: %02X-%02X-%02X-%02X-%02X-%02X\r\n",
mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]);
mf_printf(str);
mfg_scan();
ssid = ssid_get();
mfg_connect(ssid);
exit:
mico_thread_sleep(MICO_NEVER_TIMEOUT);
}
