void processTWI( void )
{
uint8_t b,p1,p2;
b = usiTwiReceiveByte();
switch (b) {
case 0x81: // set slave address
p1 = usiTwiReceiveByte();
if(p1 < 128) // Address is 7 bit
{
eeprom_update_byte(&b_slave_address, p1);
usiTwiSlaveInit(eeprom_read_byte(&b_slave_address));
}
break;
case 0x82: // clear led
led_clear();
break;
case 0x83: // set led brightness, p1=led, p2=brightness
p1 = usiTwiReceiveByte();
p2 = usiTwiReceiveByte();
set_led_pulse(p1,0); // Turn off pulsing
set_brightness(p1,p2);
break;
case 0x84: // Set to pulse led, p1=led, p2 = (0 = OFF, 1 = ON)
set_led_pulse(usiTwiReceiveByte(),usiTwiReceiveByte());
break;
case 0x85: // Dim up/down led to specific value, p1=led, p2=value to dim to
dim_led(usiTwiReceiveByte(),usiTwiReceiveByte());
break;
case 0x86: // get firmware revision
usiTwiTransmitByte(FIRMWARE_REVISION);
break;
case 0x90: // get keyUp Event
usiTwiTransmitByte(getKeyUp());
break;
case 0x91: // get KeyDown Event
usiTwiTransmitByte(getKeyDown());
break;
case 0x92: // set keyrepeat
set_keyrepeat(usiTwiReceiveByte(),usiTwiReceiveByte());
break;
case 0xFE: // reset to known state
led_clear();
button_init();
flushTwiBuffers();
break;
case 0xFF: // flush the bus
break;
default:
break;
}
}
void update_motif(void)
{
motif_t * m = db->motifs;
for (uint32_t i = 1; i < current_motif_index; i++)
m = m->next;
sprintf(current_motif_title, "%i/%i -- %s", (int)current_motif_index, (int)db->nb_motifs, m->name);
current_motif_desc = m->desc;
MULTIEDIT_SetText(motif_desc_widget, current_motif_desc);
TEXT_SetText(motif_name_widget, current_motif_title);
led_clear();
point_t * p = m->points;
while (p != NULL)
{
led_set(p->x, p->y, p->z);
p = p->next;
}
clear_points2blink();
option_t * o = m->options;
while (o != NULL)
{
handle_option(o);
o = o->next;
}
}
void led_init()
{
PEADDR = 0x02; //set alternative function (port E)
PECTL = 0x00;
PEADDR = 0x01; //set datadirection to output (port E)
PECTL = 0x00;
PGADDR = 0x02; //set alternative function (port G)
PGCTL = 0x00;
PGADDR = 0x01; //set datadirection to output (port G)
PGCTL = 0x00;
T0CTL = 0x01; //Disable Timer0 and set it to continous mode
T0CTL |= 0x38; //Set the prescale value
T0H = 0x00;
T0L = 0x01; //reset timer
T0RH = 0x00;
// T0RH = 0x02;
T0RL = 0xD0; //set reload value (0.5 ms)
IRQ0ENH &= 0xDF;
IRQ0ENL |= 0x20; //enable Timer0 interrupt, and set low priority
T0CTL |= 0x80; //enable Timer0
EI(); //enable interrupts
SET_VECTOR(TIMER0, drawtimer); //set timer interrupt function
led_clear(); //clear the LEDs
led_onall();
}
/**
* Gyroscope presission automatic bias null calibration
*/
void adis_recalibrate_gyros( void ) {
unsigned char tmp[2]; // Temporary variable
unsigned char addr[2]; // Address to TEMP_OUT
addr[0] = 0xbe; // This is the address for restoring factory calibration
addr[1] = 0x10; // This is the data portion, wich the IMU ignores when readiing
memcpy(tmp,addr,2); // Copy address to temporay variable
spi0_send(tmp,1,ADIS_CS); // Send data
printf("The gyros are being recalibrated.\n\rDON'T TOUCH THE IMU! FFS\n\r"); // Print the recieved data
led_flash(0);
led_set(0);
for(int i = 30; i>0 ; i--){
printf("%i second(s) left\n\r",i);
vTaskDelay(1000/portTICK_RATE_MS);
}
led_clear(0);
led_set(1);
vTaskDelay(500/portTICK_RATE_MS);
led_clear(1);
printf("The gyros have been recalibrated.\n\r"); // Print the recieved data
}
static void led_brightness(struct led_classdev *led_cdev,
enum led_brightness value)
{
struct cpld_led_dev *led_dev =
container_of(led_cdev, struct cpld_led_dev, cdev);
if (value)
led_set(led_dev->mask, led_dev->base);
else
led_clear(led_dev->mask, led_dev->base);
}
bool bus_power(bool enable)
{
if (enable) {
if (bus_voltage_get() > 0.5 && palReadPad(GPIOB, GPIOB_V_BUS_ENABLE) == 0) {
return false;
}
palSetPad(GPIOB, GPIOB_V_BUS_ENABLE);
} else {
led_clear(CAN1_PWR_LED);
palClearPad(GPIOB, GPIOB_V_BUS_ENABLE);
}
return true;
}
void bus_voltage_adc_conversion(void)
{
// read bus voltage
adcStartConversion(&ADCD1, &adcgrpcfg, adc_samples, ADC_BUF_DEPTH);
chBSemWait(&adc_wait);
// set LED
float voltage = bus_voltage_get();
if (voltage > 4.5f && voltage < 5.5f) {
led_set(CAN1_PWR_LED);
} else if (voltage > 0.5f || voltage > 5.5f) {
// voltage warning
led_toggle(CAN1_PWR_LED);
} else {
led_clear(CAN1_PWR_LED);
}
}
void main(void)
{
IRCF2=1; IRCF1=1; IRCF0=1; //8MHz internal RC oscillator
ADCON0 = 0b000001; //Channel 0 //A/D converter module is enabled
ADCON1 = 0b001110; //Voltage Reference //A/D Port Configuration Control bits - pin AN0
ADCON2 = 0b10000101; //A/D Result Format Select bit //000=0TAD //110=FOSC/64, 010=FOSC/32, 101=FOSC/16
T0CON=0b10010011; //prescaler 011 - 1:16 Fosc/4=2000, 2000/16=125kHz
TMR0=TMR0_LOAD; //preload
TMR0IE=1; //timer overflow intterrupt enable
PEIE=1; //peripheral interrupt enable
GIE=1; //global interrupts enable
led_init();
sbuff[0]=0xff; //light all segments
sbuff[1]=0xff;
sbuff[2]=0xff;
delay_ms(1400);
led_clear();
for(;;)
{
GODONE=1;
while(GODONE);
volt=ADRES*10/VOLT_CONT;
if(volt>999) volt=999;
sprintf(strBuff,"%2u%1u",volt/10,volt%10);
led_print(0,strBuff);
led_dot(1,1);
delay_ms(200);
}
}
/**
* Initializes the DBGU and ISO7816 driver, and starts some tests.
* \return Unused (ANSI-C compatibility)
*/
extern int main( void )
{
uint8_t Atr[MAX_ATR_SIZE] ;
uint8_t size ;
/* Disable watchdog */
wdt_disable();
/* Disable all PIO interrupts */
pio_reset_all_it();
/* Configure console */
board_cfg_console();
console_clear_screen();
console_reset_cursor();
/* Configure PIT. Must be always ON, used for delay */
printf("Configure PIT \n\r");
timer_configure(BLINK_PERIOD);
printf( "-- USART ISO7816 Example %s --\n\r", SOFTPACK_VERSION ) ;
printf( "-- %s\n\r", BOARD_NAME ) ;
printf( "-- Compiled: %s %s --\n\r", __DATE__, __TIME__ ) ;
#ifdef CONFIG_HAVE_PMIC_ACT8945A
pio_configure(act8945a_pins, ARRAY_SIZE(act8945a_pins));
if (act8945a_configure(&act8945a, &act8945a_twid)) {
act8945a_set_regulator_voltage(&act8945a, 6, 2500);
act8945a_enable_regulator(&act8945a, 6, true);
} else {
printf("--E-- Error initializing ACT8945A PMIC\n\r");
}
#endif
/* PIO configuration for LEDs */
printf("Configure LED PIOs.\n\r");
_configure_leds();
led_set(LED_BLUE);
timer_wait(500);
led_clear(LED_BLUE);
led_status[LED_BLUE] = 1;
/* PIO configuration for Button, use to simulate card detection. */
printf("Configure buttons with debouncing.\n\r");
_configure_buttons();
/* Configure Pios usart*/
pio_configure(&pins_com2[0], ARRAY_SIZE(pins_com2));
/* Init ISO7816 interface */
iso7816_init(&iso7816_desc, &iso7816_opt);
/* Warm reset */
iso7816_warm_reset(&iso7816_desc);
/* Read ATR */
memset( Atr, 0, sizeof(Atr) ) ;
iso7816_get_data_block_ATR(&iso7816_desc, Atr, &size );
/* Decode ATR */
iso7816_decode_ATR(Atr);
/* Allow user to send some commands */
_send_receive_commands(&iso7816_desc);
printf("\n\r Exit App \n\r");
while (1) ;
}
void ui_state_game(void)
{
int i, x, y, go_x, go_y, result;
int aimline_x1 = SCREEN_WIDTH - UI_TILE_WIDTH / 2,
aimline_y1 = UI_Y_OFFSET + UI_TILE_HEIGHT / 2,
aimline_x2, aimline_y2, strengthbar_width;
int play_explosion = 0;
int tank_direction, tank_strength, meter_direction;
double radians;
game_position_t result_pos;
image_t *tile;
led_clear();
for (i = 0; i < game_soldier_score; i++)
led_set(7 - i, 1);
for (i = 0; i < game_tank_score; i++)
led_set(i, 1);
if (game_soldier_score >= UI_MAX_POINTS ||
game_tank_score >= UI_MAX_POINTS) {
ui_state = UI_SCOREBOARD;
return;
}
game_reset();
while (1) {
screen_clear(color_black);
for (x = 0; x < GAME_WIDTH; x++)
for (y = 0; y < GAME_HEIGHT; y++) {
tile = game_is_scorched[y][x] ? img_dirt : img_grass;
image_draw(x * UI_TILE_WIDTH, y * UI_TILE_HEIGHT + UI_Y_OFFSET, tile);
}
go_x = game_player.x; go_y = game_player.y;
switch (ui_player_direction) {
case GAME_NORTH: go_y--; break;
case GAME_SOUTH: go_y++; break;
case GAME_WEST: go_x--; break;
case GAME_EAST: go_x++; break;
}
switch (ui_state) {
case UI_GAME_SOLDIER:
if (go_x >= 0 && go_x < GAME_WIDTH &&
go_y >= 0 && go_y < GAME_HEIGHT) {
screen_rectangle(
go_x * UI_TILE_WIDTH,
go_y * UI_TILE_HEIGHT + UI_Y_OFFSET,
UI_TILE_WIDTH,
UI_TILE_HEIGHT,
color_blue);
}
if (ui_play_point_sound)
snd_play("sounds/point.raw");
else if (play_explosion)
snd_play("sounds/eksplosjon.raw");
ui_play_point_sound = 0;
play_explosion = 0;
if (btn_is_pushed(7)) {
result = game_move_player(ui_player_direction);
if (result == GAME_MOVE_TANK) {
ui_play_point_sound = 1;
return;
}
if (result == GAME_MOVE_OK) {
tank_direction = GAME_MIN_DIRECTION;
meter_direction = UI_DIRECTION_SPEED;
ui_state = UI_GAME_DIRECTION;
}
}
if (btn_is_pushed(6)) {
ui_player_direction = ((int)ui_player_direction + 1) % 4;
}
break;
case UI_GAME_DIRECTION:
if (btn_is_pushed(0)) {
tank_strength = GAME_MIN_STRENGTH;
meter_direction = UI_STRENGTH_SPEED;
ui_state = UI_GAME_STRENGTH;
break;
}
radians = tank_direction * M_PI / 180;
aimline_x2 = aimline_x1 - (int)(cos(radians) * UI_TILE_WIDTH * 3);
aimline_y2 = aimline_y1 + (int)(sin(radians) * UI_TILE_HEIGHT * 3);
screen_line(aimline_x1, aimline_y1, aimline_x2, aimline_y2, color_red);
if (tank_direction >= GAME_MAX_DIRECTION)
meter_direction = -UI_DIRECTION_SPEED;
if (tank_direction <= GAME_MIN_DIRECTION)
meter_direction = UI_DIRECTION_SPEED;
tank_direction += meter_direction;
tank_direction = MAX(GAME_MIN_DIRECTION, tank_direction);
tank_direction = MIN(GAME_MAX_DIRECTION, tank_direction);
break;
case UI_GAME_STRENGTH:
if (btn_is_pushed(0)) {
snd_play_wait("sounds/skyte.raw");
result_pos = game_shoot_bullet(tank_direction, tank_strength);
ui_state = UI_GAME_SOLDIER;
play_explosion = !game_position_equals(result_pos,
GAME_SHOT_OOB);
if (result_pos.x < 0 && result_pos.y < 0) {
ui_play_point_sound = 1;
return;
}
break;
}
screen_line(aimline_x1, aimline_y1, aimline_x2, aimline_y2, color_red);
strengthbar_width = tank_strength *
(SCREEN_WIDTH - UI_TILE_WIDTH) / GAME_MAX_STRENGTH;
screen_fill_rectangle(
SCREEN_WIDTH - UI_TILE_WIDTH / 2 - strengthbar_width,
UI_TILE_HEIGHT / 2,
strengthbar_width,
UI_TILE_HEIGHT,
color_red);
if (tank_strength >= GAME_MAX_STRENGTH)
meter_direction = -UI_STRENGTH_SPEED;
if (tank_strength <= GAME_MIN_STRENGTH)
meter_direction = UI_STRENGTH_SPEED;
tank_strength += meter_direction;
tank_strength = MAX(GAME_MIN_STRENGTH, tank_strength);
tank_strength = MIN(GAME_MAX_STRENGTH, tank_strength);
break;
}
image_draw(
(GAME_WIDTH - 2) * UI_TILE_WIDTH,
UI_Y_OFFSET,
img_tank);
image_draw(
game_player.x * UI_TILE_WIDTH,
game_player.y * UI_TILE_HEIGHT + UI_Y_OFFSET,
img_soldier);
screen_show_buffer();
}
}
/**
* This reads all sensor data from the ADIS sesnor via burst read mode
*/
void adis_burst_read(void * pvParameters) {
unsigned char addr[2]; // Temporary variable
portTickType xLastWakeTime; // Variable for the vTaskDelayUntil()
xLastWakeTime = xTaskGetTickCount(); // Start the counting for the ticktimer
while(1){
if (sample_output_type > ADIS_STOP) { // Do not sample
if (sample_output_type >= ADIS_SILENT) { // Do the sampling
led_set(2);
addr[0] = 0x3e;
addr[1] = 0x00;
spi0_send(addr,1,ADIS_CS); //Initiate burst read mode
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(SUPPLY_OUT,1,ADIS_CS); //Power supply measurement
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(XGYRO_OUT,1,ADIS_CS); //X-axis gyroscope output
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(YGYRO_OUT,1,ADIS_CS); //Y-axis gyroscope output
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(ZGYRO_OUT,1,ADIS_CS); //Z-axis gyroscope output
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(XACCL_OUT,1,ADIS_CS); //X-axis accelerometer output
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(YACCL_OUT,1,ADIS_CS); //Y-axis accelerometer output
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(ZACCL_OUT,1,ADIS_CS); //Z-axis accelerometer output
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(XMAGN_OUT,1,ADIS_CS); //X-axis magnetometer measurement
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(YMAGN_OUT,1,ADIS_CS); //Y-axis magnetometer measurement
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(ZMAGN_OUT,1,ADIS_CS); //Z-axis magnetometer measurement
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(TEMP_OUT,1,ADIS_CS); //Temperature output
vTaskDelay(.01/portTICK_RATE_MS);
spi0_send(AUX_ADC,1,ADIS_CS); //Auxiliary ADC measurement
}
if (sample_output_type == ADIS_CSV) { // Output CSV format
// Supply voltage decoding
unsigned int voltage;
voltage = (unsigned int)((SUPPLY_OUT[0] << 8) | SUPPLY_OUT[1]) & 0x3fff;
voltage = voltage * 242;
printf("%d,",voltage);
//======================GYROS=======================
//xgyro
printf("%d,",adis_decode_14bit_raw(XGYRO_OUT,50)); // Print the recieved data
//ygyro
printf("%d,",adis_decode_14bit_raw(YGYRO_OUT,50)); // Print the recieved data
//zgyro
printf("%d,",adis_decode_14bit_raw(ZGYRO_OUT,50)); // Print the recieved data
//======================ACCLEROMETERS=======================
//xaccl
printf("%d,",adis_decode_14bit_raw(XACCL_OUT,3330)); // Print the recieved data
//yaccl
printf("%d,",adis_decode_14bit_raw(YACCL_OUT,3330)); // Print the recieved data
//zaccl
printf("%d,",adis_decode_14bit_raw(ZACCL_OUT,3330)); // Print the recieved data
//======================MAGNETOMETERS=======================
//xmag
printf("%d,",adis_decode_14bit_raw(XMAGN_OUT,500)); // Print the recieved data
//ymag
printf("%d,",adis_decode_14bit_raw(YMAGN_OUT,500)); // Print the recieved data
//zmag
printf("%d,",adis_decode_14bit_raw(ZMAGN_OUT,500)); // Print the recieved data
// Temperature @TODO This is not tested yet
printf("%d,",(adis_decode_12bit_raw(TEMP_OUT,140)+25000)); // Print the recieved data
// ADC @TODO This is not tested or verified yet
printf("%d\n\r",adis_decode_12bit_raw(AUX_ADC,810)); // Print the recieved data
}
if (sample_output_type == ADIS_BIN) { // Output binary format
printf("%c%c", SUPPLY_OUT[0], SUPPLY_OUT[1]); //Power supply measurement
printf("%c%c", XGYRO_OUT[0], XGYRO_OUT[1]); //X-axis gyroscope output
printf("%c%c", YGYRO_OUT[0], YGYRO_OUT[1]); //Y-axis gyroscope output
printf("%c%c", ZGYRO_OUT[0], ZGYRO_OUT[1]); //Z-axis gyroscope output
printf("%c%c", XACCL_OUT[0], XACCL_OUT[1]); //X-axis accelerometer output
printf("%c%c", YACCL_OUT[0], YACCL_OUT[1]); //Y-axis accelerometer output
printf("%c%c", ZACCL_OUT[0], ZACCL_OUT[1]); //Z-axis accelerometer output
printf("%c%c", XMAGN_OUT[0], XMAGN_OUT[1]); //X-axis magnetometer measurement
printf("%c%c", YMAGN_OUT[0], YMAGN_OUT[1]); //Y-axis magnetometer measurement
printf("%c%c", ZMAGN_OUT[0], ZMAGN_OUT[1]); //Z-axis magnetometer measurement
printf("%c%c", TEMP_OUT[0], TEMP_OUT[1]); //Temperature output
printf("%c%c", AUX_ADC[0], AUX_ADC[1]); //Auxiliary ADC measurement
printf("\n\r"); // Newline and return
}
led_clear(2);
}
//------Here a datacollecter is implemented---
dc_collector[dc_counter] = 9.82*((float)(adis_decode_14bit_raw(XACCL_OUT,3330))/1000000); // Collect 10 values
// printf("accx=\t%d\n\r",(int)(dc_collector[dc_counter]*1000)); // Prints in mili g
dc_counter++;
if (dc_counter == 10){
dc_collector_avg = 0;
for( sum_counter = 0 ; sum_counter < 10 ; sum_counter++){
dc_collector_avg = dc_collector_avg + dc_collector[sum_counter]; // Sum up the last 10 values
}
dc_collector_avg = dc_collector_avg/10; // Calculate average of 10 collected values
printf("avg\t%d mm/s^2\t",(int)(dc_collector_avg*1000));
// Integrate twice
dc_collector_speed = dc_collector_speed + (dc_collector_avg*0.5);
printf("Speed=\t%d mm/s\t",(int)(dc_collector_speed*1000));
dc_collector_distance = dc_collector_distance + (dc_collector_speed*0.5);
printf("Distance:\t%d mm\n\r",(int)(dc_collector_distance*1000));
dc_counter = 0;
}
//------Here a datacollecter is implemented (end)---
vTaskDelayUntil( &xLastWakeTime, 50/portTICK_RATE_MS);
}
}
int main(void)
{
// uint8_t rgb[3];
led_init();
button_init();
commstack_init(COMM_DEV, COMM_BAUDRATE);
// uartbridge_send1("Hello UART 1\n", 13);
// uartbridge_send2("Hello UART 2\n", 13);
pwm_init();
// SysTick_Config(48000 * 40); // set systick interrupt to be triggered every 40ms
// SystemCoreClockUpdate();
while (1) {
// while (USART_GetFlagStatus(UART_2_DEV, USART_FLAG_TXE) == RESET);
// USART_SendData(UART_2_DEV, 'X');
if (GPIO_ReadInputDataBit(GPIOA, GPIO_Pin_0)) {
led_set();
++pushed;
} else {
pushed = 0;
led_clear();
}
if (pushed >= PUSH_LIMIT) {
pushed = 0;
state = ((state + 1) == STATE_END) ? 0 : state + 1;
led_blink();
}
// switch (state) {
// case STATE_R:
// rgb[0] = 150;
// rgb[1] = 0;
// rgb[2] = 0;
// pwm_set(rgb);
// break;
// case STATE_G:
// rgb[0] = 0;
// rgb[1] = 155;
// rgb[2] = 0;
// pwm_set(rgb);
// break;
// case STATE_B:
// rgb[0] = 0;
// rgb[1] = 0;
// rgb[2] = 155;
// pwm_set(rgb);
// break;
// case STATE_RG:
// rgb[0] = 155;
// rgb[1] = 155;
// rgb[2] = 0;
// pwm_set(rgb);
// break;
// case STATE_GB:
// rgb[0] = 0;
// rgb[1] = 155;
// rgb[2] = 155;
// pwm_set(rgb);
// break;
// case STATE_BR:
// rgb[0] = 155;
// rgb[1] = 0;
// rgb[2] = 155;
// pwm_set(rgb);
// break;
// case STATE_SLIDE:
// break;
// default:
// rgb[0] = 0;
// rgb[1] = 0;
// rgb[2] = 0;
// pwm_set(rgb);
// break;
// }
}
return 0;
}
void led_blink_clear(u8 mask, u16 *base)
{
led_clear(mask, base);
}
void flash(int led) {
led_set(led);
delay(DELAY);
led_clear(led);
delay(DELAY);
}
void process_bytes(){
uint16_t nb_received = CDC_Device_BytesReceived(&VirtualSerial_CDC_Interface);
uint8_t c;
for( uint16_t i = 0; i < nb_received ; i++ ){
c = CDC_Device_ReceiveByte(&VirtualSerial_CDC_Interface);
switch (c){
case 'l':
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
for (uint8_t x = 0; x < 255; x++){
led_set(255,20,x);
Delay_MS(10);
}
led_clear();
println("LED test finished");
break;
#ifdef ONBOARD_STUFF
case 'm':{
switch (motor_get()){
case 0: // TODO use ranges instead of exact values
println("Motor ON (PWM @255)");
motor_set(255);
break;
case 255:
println("Motor ON (PWM @100)");
motor_set(100);
break;
case 100:
println("Motor OFF");
motor_set(0);
break;
}
}break;
case 'd':{
fprintf(&USBSerialStream, "GP2Y PM: %.1f ug/m3\r\n", gp2y_get_pm() );
}break;
case 'k':
fprintf(&USBSerialStream, "humidity: %.0f %%\r\n", cc2dxx_get_humidity());
Delay_MS(100);
fprintf(&USBSerialStream, "temp: %.2f deg C\r\n", cc2dxx_get_temperature());
break;
#endif
#ifdef SENSORBOARD
case 'i':
fprintf(&USBSerialStream, "TCOV: %d\r\n", iaqengine_get_ppm());
break;
#endif
#ifdef WIFI
case 'w':
wifi_print_MAC();
wifi_print_ip();
break;
case 'y':
wifi_config_set_dev();
wifi_connect_to_ap(wifi_ap_ssid, wifi_ap_password, wifi_ap_encrypt_mode);
wifi_print_ip();
wifi_ping(192,168,1,1);
break;
case 's':
wifi_resolve_backend_ip();
break;
/*case 'e':
fprintf(&USBSerialStream, "is set? %u\r\n", wifi_config_is_set());
fprintf(&USBSerialStream, "set dev %u\r\n", wifi_config_set_dev());
fprintf(&USBSerialStream, "is set? %u\r\n", wifi_config_is_set());
fprintf(&USBSerialStream, "save %u\r\n", wifi_config_save());
fprintf(&USBSerialStream, "%s %s %u\r\n", wifi_ap_ssid, wifi_ap_password, wifi_ap_encrypt_mode);
fprintf(&USBSerialStream, "set lol %u\r\n", wifi_config_set("lol", "lolilol", 2));
fprintf(&USBSerialStream, "%s %s %u\r\n", wifi_ap_ssid, wifi_ap_password, wifi_ap_encrypt_mode);
fprintf(&USBSerialStream, "load %u\r\n", wifi_config_load());
fprintf(&USBSerialStream, "%s %s %u\r\n", wifi_ap_ssid, wifi_ap_password, wifi_ap_encrypt_mode);
wifi_config_mem_clear();
fprintf(&USBSerialStream, "clear then load %u\r\n", wifi_config_load());
break;*/
case 'p':{
println("Trying to POST");
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
wifi_config_set_dev();
/* // There is a problem with that, it hangs sometimes ><
if (!wifi_config_is_set()){
if (!wifi_config_load()){
#ifdef DEV
printf("setting up DEV config");
wifi_config_set_dev();
#else
printf("No config anywhere!");
return;
// TODO what do we do if it's not configured?
#endif
}
}*/
fprintf(&USBSerialStream, "%s %s %u\r\n", wifi_ap_ssid, wifi_ap_password, wifi_ap_encrypt_mode);
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
// TODO check if the SSID is available before trying to connect or it might hang... :/
if( !wifi_connect_to_ap(wifi_ap_ssid, wifi_ap_password, wifi_ap_encrypt_mode) == WERR_OK){
println("AP NOK");
} else {
println("AP OK");
wifi_print_ip();
uint32_t backend_ip;
uint16_t backend_port = 80;
//backend_ip = cc3000_IP2U32(54,221,218,154);
//backend_ip = cc3000_IP2U32(67,215,65,132);
//backend_ip = cc3000_IP2U32(192,168,1,11);
//backend_ip = cc3000_IP2U32(192,168,42,102);
backend_ip = wifi_resolve_backend_ip();
print_ip_helper("backend", backend_ip);
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
if (cc3000_ping(backend_ip, 3, 500, 32)){
fprintf(&USBSerialStream, "ping OK\r\n");
} else {
fprintf(&USBSerialStream, "ping timeout\r\n");
}
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
void* sock = cc3000_connectTCP(backend_ip, backend_port);
if (cc3000_cli_connected(sock)){
println("cli connected");
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
uint16_t res = 0;
res += cc3000_cli_fastrprint(sock, "POST /v1/airboxlab/ HTTP/1.1\n");
res += cc3000_cli_fastrprint(sock, "User-Agent: abl1.0\n");
res += cc3000_cli_fastrprint(sock, "Host: api.airboxlab.com\n");
res += cc3000_cli_fastrprint(sock, "Accept: */*\n");
//res += cc3000_cli_fastrprint(sock, "Content-Type: application/json\n");
res += cc3000_cli_fastrprint(sock, "Content-Length: 35\n\n");
res += cc3000_cli_fastrprint(sock, "5040f3bd20c8,20.7,53.9,1255,11.1,78\n");
fprintf(&USBSerialStream, "written: %u / %u\r\n", res, 171);
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
Delay_MS(1000);
uint8_t nb_available = cc3000_cli_available(sock);
fprintf(&USBSerialStream, "Returned %u\r\n", nb_available);
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
for (int i = 0; i<cc3000_cli_available(sock); i++){
fprintf(&USBSerialStream, "%c" ,cc3000_cli_read(sock));
}
println("");
cc3000_cli_close(sock);
println("closed");
} else {
println("cli not connected");
}
}
}break;/*
case 'W':{ // setup wifi
int nb_returned;
println("SSID?");
println("password?");
println("encryption mode number?[0:none, 1:WEP, 2:WPA, 3:WPA2]");
uint16_t _mode;
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
while(1){ // TODO timeout? opt-out?
_mode = fgetc(&USBSerialStream);
printf("read: %i", _mode);
if(_mode <= 3){
wifi_ap_encrypt_mode = _mode;
fprintf(&USBSerialStream, "Mode = %u\r\n", _mode);
break;
} else {
fprintf(&USBSerialStream, "Not a valid mode. Please choose number between [0:none, 1:WEP, 2:WPA, 3:WPA2]\r\n");
CDC_Device_USBTask(&VirtualSerial_CDC_Interface);
USB_USBTask();
}
}
}break;*/
#endif
default:
println("Airboxlab serial mode: press 'l' key to test LEDs");
break;
}
}
}
int main ( void ) {
char* line;
time_t* led_flash_timer;
time_t* reboot_timer;
socket_t* socket = socket0_g;
int reboot_stage = 0;
/* Turn off all LEDs as a starting point */
led_clear();
/* this must be first, because all the other init functions call malloc */
init_malloc();
/* Initialize current time and some timers */
init_current_time();
led_flash_timer = init_timer();
set_timer(led_flash_timer, 500);
reboot_timer = init_timer();
/* receive packet buffer */
rx_packet_g = malloc(sizeof(packet_t));
/* socket init */
socket0_g = init_socket(0);
socket1_g = init_socket(1);
/* open ethernet port and wait for connection requests
keep trying forever */
while (!open_link());
/* infinite loop. Everything is timer, interrupt and queue driven from here on down */
while (1) {
/* Flash a heartbeat LED */
if (timer_expired(led_flash_timer)) {
led_flip(0);
set_timer(led_flash_timer, 500);
}
/* Check for newly downloaded tftp file. Add to all tx buffers */
/* Has a file been uploaded via tftp ? */
if (udp_file_g != NULL) {
/* Notify telnet clients that file has been received */
if (udp_file_g->ready) {
udp_file_g->ready = 0;
telnet_broadcast("Received file %s, %d bytes, linux %d\r\n",
udp_file_g->filename, udp_file_g->total_bytes, udp_file_g->linux_boot);
if (process_file(socket0_g) == 0)
/* Disconnect in 1 second */
set_timer(reboot_timer, 1000);
else
telnet_broadcast("Not an elf file\r\n");
}
}
/* reboot timer expired */
if (timer_expired(reboot_timer)) {
/* First stage of reboot sequence is to nicely disconnect */
if (reboot_stage == 0) {
set_timer(reboot_timer, 1000);
reboot_stage = 1;
socket0_g->tcp_disconnect = 1;
socket1_g->tcp_disconnect = 1;
}
else {
/* Second stage of reboot sequence is to turn off ethmac and then jump to restart vector */
close_link();
reboot();
}
}
/* Poll both sockets in turn for activity */
if (socket == socket0_g)
socket = socket1_g;
else
socket = socket0_g;
/* Check if any tcp packets need to be re-transmitted */
tcp_retransmit(socket);
/* Handle exit command */
if (socket->tcp_disconnect && socket->tcp_connection_state == TCP_OPEN) {
tcp_disconnect(socket);
}
/* Reset connection */
if (socket->tcp_reset) {
socket->tcp_connection_state = TCP_CLOSED;
socket->telnet_connection_state = TELNET_CLOSED;
socket->telnet_options_sent = 0;
tcp_reply(socket, NULL, 0);
socket->tcp_reset = 0;
}
/* Send telnet options */
if (socket->tcp_connection_state == TCP_OPEN && !socket->telnet_options_sent){
telnet_options(socket);
socket->telnet_options_sent = 1;
}
/* telnet connection open
Communicate with client */
else if (socket->telnet_connection_state == TELNET_OPEN) {
/* Send telnet greeting */
if (!socket->telnet_sent_opening_message){
put_line (socket->telnet_txbuf, "Amber Processor Boot Loader\r\n> ");
socket->telnet_sent_opening_message = 1;
}
/* Parse telnet rx buffer */
if (get_line(socket->telnet_rxbuf, &line))
parse_command (socket, line);
/* Transmit text from telnet tx buffer */
telnet_tx(socket, socket->telnet_txbuf);
}
}
}
