Esempio n. 1
0
void sys_tick_handler(void)
{
	static int temp32 = 0;
	static uint8_t data[8] = {0, 1, 2, 0, 0, 0, 0, 0};

	/* We call this handler every 1ms so 1000ms = 1s on/off. */
	if (++temp32 != 1000)
		return;

	temp32 = 0;

	/* Transmit CAN frame. */
	data[0]++;
	if (can_transmit(CAN1,
			 0,     /* (EX/ST)ID: CAN ID */
			 false, /* IDE: CAN ID extended? */
			 false, /* RTR: Request transmit? */
			 8,     /* DLC: Data length */
			 data) == -1)
	{
		gpio_set(GPIOA, GPIO6);		/* LED0 off */
		gpio_set(GPIOA, GPIO7);		/* LED1 off */
		gpio_clear(GPIOB, GPIO0);	/* LED2 on */
		gpio_set(GPIOB, GPIO1);		/* LED3 off */
	}
}
Esempio n. 2
0
File: em-stop.c Progetto: GBert/misc
void usb_lp_can_rx0_isr(void) {
    uint32_t id, fmi;
    bool ext, rtr;
    uint8_t dlc, data[8];

    can_receive(CAN1, 0, false, &id, &ext, &rtr, &fmi, &dlc, data);
    can_fifo_release(CAN1, 0);

    /* check for extended id, dlc = 5 and id 0x0000xxxx */
    if ((ext) && (dlc == 5) && !(id & 0xffff0000)) {
	/* M*rklin Start/Stop CMD
	   00004711 [5] 00 00 00 00 00 -> Stop
	   00004711 [5] 00 00 00 00 01 -> Start
	 */
	if (data[4] && 0x01)
	    if (!status) {
		/* send stop immediatly if Stop Button pressed */
		can_transmit(CAN1, 0x0000fffe, true, false, 5, data);
		gpio_set(GPIOC, GPIO13);	/* clear green LED */
		gpio_set(GPIOB, GPIO4);		/* clear On LED */
		gpio_clear(GPIOB, GPIO5);	/* light Off LED */
	    } else {
		gpio_clear(GPIOC, GPIO13);	/* light green LED */
		gpio_clear(GPIOB, GPIO4);	/* light On LED */
		gpio_set(GPIOB, GPIO5);		/* clear Off LED */
	} else {
	    gpio_set(GPIOC, GPIO13);		/* clear green LED */
	    gpio_set(GPIOB, GPIO4);		/* clear On LED */
	    gpio_clear(GPIOB, GPIO5);		/* light Off LED */
	}
    }
}
Esempio n. 3
0
void can_write_vstats(unsigned int StringNo, unsigned int* vcell, unsigned int* temperature, unsigned int isense)
{
	unsigned int i, a;

	//Prepare a CAN message for these cell voltages
	if(StringNo == BATT_S1) 	{can_push_ptr->address = BMS_S1_CAN_BASE;}
	else 					 	{can_push_ptr->address = BMS_S2_CAN_BASE;}
	can_push_ptr->address += BMS_STAT;

	// Sum up all cell voltages in stack
	a = 0;
	for ( i = 0; i < 30; i++ )
	{
		a += ( vcell[i] / 10 );
	}
	can_push_ptr->data.data_u16[0] = a;

	// Average temperature

	a = temperature[1] + temperature[4] + temperature[7];
	a /= 3;
	can_push_ptr->data.data_u16[1] = a;

	// Current measurement

	can_push_ptr->data.data_u16[2] = isense;

	can_push_ptr->status = 6;
	can_push();
    can_transmit();
}
Esempio n. 4
0
int can_hw_transmit(uint32_t id, const uint8_t *buf, uint8_t len)
{

  if (!can_initialized) {
    return -2;
  }

  if(len > 8){
    return -1;
  }


  /* FIXME: we are discarding the const qualifier for buf here.
   * We should probably fix libopencm3 to actually have the
   * const qualifier too...
   */
  return can_transmit(CAN1,
                      id,     /* (EX/ST)ID: CAN ID */
#ifdef USE_CAN_EXT_ID
                      true,  /* IDE: CAN ID extended */
#else
                      false, /* IDE: CAN ID not extended */
#endif
                      false, /* RTR: Request transmit? */
                      len,   /* DLC: Data length */
                      (uint8_t *)buf);
}
Esempio n. 5
0
void sys_tick_handler(void)
{
	static int temp32 = 0;
	static u8 data[8] = {0, 1, 2, 0, 0, 0, 0, 0};

	/* We call this handler every 1ms so 100ms = 1s
	 * Resulting in 100Hz message frequency.
	 */
	if (++temp32 != 100)
		return;

	temp32 = 0;

	/* Transmit CAN frame. */
	data[0]++;
	if (can_transmit(CAN1,
			 0,     /* (EX/ST)ID: CAN ID */
			 false, /* IDE: CAN ID extended? */
			 false, /* RTR: Request transmit? */
			 8,     /* DLC: Data length */
			 data) == -1)
	{
		gpio_set(GPIOA, GPIO8);		/* LED0 off */
		gpio_set(GPIOB, GPIO4);		/* LED1 off */
		gpio_set(GPIOC, GPIO15);       	/* LED2 off */
		gpio_set(GPIOC, GPIO2);         /* LED3 off */
		gpio_clear(GPIOC, GPIO5);	/* LED4 on */
	}
}
int aseba_can_send(const uint16_t *msg, int len)
{
    if (can_transmit(CAN1, ASEBA_ID | ASEBA_TYPE_SMALL_PACKET, false, false, len*2, (uint8_t*)msg) >= 0) {
        // uart_puts("x");
        return 0;
    } else {
        uart_puts("ERROR sending frame\n");
        return -1;
    }
}
Esempio n. 7
0
void can_write_gear(unsigned int StringNo, unsigned int *gear_num)
{
	//Prepare a CAN message for gear number
	if(StringNo == SCU_GEAR_S1) 	{can_push_ptr->address = SCU_S1_CAN_BASE;}
	can_push_ptr->address += SCU_GEAR;
	can_push_ptr->data.data_u16[0] = gear_num[0];
	can_push_ptr->current_gear = gear_num[0];
	can_push_ptr->status = gear_num[0];
	can_push();
    can_transmit();
}
Esempio n. 8
0
//-----------------------------------------------
void can_in_an(void)
{
char temp,i;
signed temp_S;
int tempI;



//if((mess[0]==1)&&(mess[1]==2)&&(mess[2]==3)&&(mess[3]==4)&&(mess[4]==5)&&(mess[5]==6)&&(mess[6]==7)&&(mess[7]==8))can_transmit1(1,2,3,4,5,6,7//,8);


if((mess[6]==ADRESS)&&(mess[7]==ADRESS)&&(mess[8]==GETTM))	
	{ 
	
	can_error_cnt=0;
	
	can_transmit(0x18e,ADRESS,PUTTM_NET,*(((char*)&unet_buff[0])+1),*((char*)&unet_buff[0]),*(((char*)&unet_buff[1])+1),*((char*)&unet_buff[1]),*(((char*)unet_buff[2])+1),*((char*)unet_buff[2]));
     link_cnt=0;
     link=ON;
     
 /*    if(flags_tu&0b10000000)
     	{
     	if(!res_fl)
     		{             
     		res_fl=1;
     		bRES=1;
     		res_fl_cnt=0;
     		}
     	}
     else 
     	{
     	if(main_cnt>20)
     		{
    			if(res_fl)
     			{
     			res_fl=0;
     			}
     		}
     	}	
     	
      if(res_fl_)
      	{
      	res_fl_=0;
      	} */    	
	}




can_in_an_end:
bCAN_RX=0;
}   
Esempio n. 9
0
//Write set of 3 temperature readings from a single string to CAN bus
void can_write_temps(unsigned int StringNo, unsigned int* temp)
{
	//Prepare a CAN message for these temperatures
	if(StringNo == BATT_S1) 	{can_push_ptr->address = BMS_S1_CAN_BASE;}
	else 					 	{can_push_ptr->address = BMS_S2_CAN_BASE;}
	can_push_ptr->address += BMS_TEMP;
	can_push_ptr->data.data_u16[0] = temp[1];
	can_push_ptr->data.data_u16[1] = temp[4];
	can_push_ptr->data.data_u16[2] = temp[7];
	can_push_ptr->status = 6;
	can_push();
    can_transmit();
}
Esempio n. 10
0
LONG cop_transmit(LONG cob_id, SHORT length, BYTE *data)
{
	// 1. Configure transmit message object
	if((cop_error = can_config(CANBUF_TX, cob_id, CANMSG_TRANSMIT)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		return cop_error;
	}
	// 2. Transmit the message
	if((cop_error = can_transmit(CANBUF_TX, length, data)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		return cop_error;
	}
	// Return if the message is transmitted
	can_delete(CANBUF_TX);
	return cop_error;
}
Esempio n. 11
0
static inline void main_periodic( void ) {

  /*RunOnceEvery(10, {DOWNLINK_SEND_ALIVE(DefaultChannel, 16, MD5SUM);});*/

  //RunOnceEvery(5, {DOWNLINK_SEND_ADC_GENERIC(DefaultChannel, &coder_values[0], &coder_values[1]);});
  //RunOnceEvery(5, {DOWNLINK_SEND_ADC_GENERIC(DefaultChannel, &can1_status, &can1_pending);});

  /*RunOnceEvery(5, {DOWNLINK_SEND_BETH(DefaultChannel, &bench_sensors.angle_1,
    &bench_sensors.angle_2,&bench_sensors.angle_3, &bench_sensors.current);});*/

  servos[0]=coder_values[0];
  servos[1]=coder_values[1];
  //use id=1 for azimuth board
  can_transmit(1, (uint8_t *)servos, 8);
  LED_TOGGLE(5);
}
Esempio n. 12
0
int can_trans(uint32_t id, const uint8_t *buf, uint8_t len)
{
	if(len > 8){
		return -1;
	}

	can_tx_msg.id = id;
	can_tx_msg.dlc = len;

	memcpy(can_tx_msg.data, buf, len);

	return can_transmit(CAN1,
			    can_tx_msg.id,
			    can_tx_msg.ide,
			    can_tx_msg.rtr,
			    can_tx_msg.dlc,
			    can_tx_msg.data);
}
Esempio n. 13
0
bool can_interface_send_message(uint32_t id, uint8_t *message, uint8_t length, uint32_t retries)
{
    do {
        can_transmit(
            CAN1,       // canport
            id,         // can id
            false,      // extended id
            false,      // request transmit
            length,     // data length
            message     // data
        );

        while((CAN_TSR(CAN1) & CAN_TSR_RQCP0) == 0);

        if ((CAN_TSR(CAN1) & CAN_TSR_TXOK0)) {
            return true;    // can ok
        }
    } while (retries-- > 0);

    return false;
}
Esempio n. 14
0
void can_write_vcell(unsigned int StringNo, unsigned int* vcell)
{
	unsigned int i;
	//Prepare a CAN message for these cell voltages
	if(StringNo == BATT_S1) 	{can_push_ptr->address = BMS_S1_CAN_BASE;}
	else 					 	{can_push_ptr->address = BMS_S2_CAN_BASE;}
	can_push_ptr->address += BMS_CV;

	for ( i = 0; i < 30; i += 4 )
	{
		can_push_ptr->data.data_u16[0] = vcell[i];
		can_push_ptr->data.data_u16[1] = vcell[i+1];
		if ( i+2 < 30 )
		{
			can_push_ptr->data.data_u16[2] = vcell[i+2];
			can_push_ptr->data.data_u16[3] = vcell[i+3];
		}
		can_push_ptr->status = 8;
		can_push();
	    can_transmit();
		can_push_ptr->address++;
	}
}
Esempio n. 15
0
// ********************************
// Error Transmit
// ********************************
void dn_error_transmit(void){
  can_transmit(&tx_fd_error);
}
Esempio n. 16
0
static LONG sdo_receive(BYTE node_id, WORD index, BYTE subindex, SHORT *length, BYTE *data, SHORT max)
{
	short n;							// data length code
	short rc;							// return value
	short t = 0;						// toggle bit
	
	// ---  Initiate SDO Upload  ---
	cop_buffer[0] = 0x40;				// client command specifier
	cop_buffer[1] = LOBYTE(index);		// multiplexor: index (LSB)
	cop_buffer[2] = HIBYTE(index);		//              index (MSB)
	cop_buffer[3] = (BYTE)(subindex);	//              subindex
	cop_buffer[4] = 0x00;				// reserved: set to 00h
	cop_buffer[5] = 0x00;				//   -"-
	cop_buffer[6] = 0x00;				//   -"-
	cop_buffer[7] = 0x00;				//   -"-
	n = 8;								// 8 bytes to transmit!

	// 1. Configure transmit message object for client SDO
	if((cop_error = can_config(CANBUF_TX, SDO_CLIENT + node_id, CANMSG_TRANSMIT)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		return cop_error;
	}
	// 2. Configure receive message object for server SDO 
	if((cop_error = can_config(CANBUF_RX, SDO_SERVER + node_id, CANMSG_RECEIVE)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		can_delete(CANBUF_RX);
		return cop_error;
	}
	// 2. Transmit the client SDO message
	if((cop_error = can_transmit(CANBUF_TX, n, cop_buffer)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		can_delete(CANBUF_RX);
		return cop_error;
	}
	// 3. Start timer for SDO time-out
	can_start_timer(cop_timeout);

	// 4. Wait until server message is received
	do	{
		switch((rc = can_receive(CANBUF_RX, &n, cop_buffer)))
		{
		case CANERR_NOERROR:			// confirmation:
			if(n != 8) {								// 8 bytes received?
				cop_error = SDOERR_GENERAL_ERROR;		//   abort: general error
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
			   *length = 0;								//   no data received!
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_LENGTH;
			}
			if((cop_buffer[1] != LOBYTE(index)) ||		// multiplexor? index (LSB)
			   (cop_buffer[2] != HIBYTE(index)) ||		//              index (MSB)
			   (cop_buffer[3] != (BYTE)(subindex))) {	//              subindex
				rc = COPERR_FORMAT;
				break;
			}
			if((cop_buffer[0] & 0xE0) == 0x80) {// SDO abort received?
				LOLOBYTE(cop_error) = cop_buffer[4];	//   abort code (LSB)
				LOHIBYTE(cop_error) = cop_buffer[5];	//    -"-
				HILOBYTE(cop_error) = cop_buffer[6];	//    -"-
				HIHIBYTE(cop_error) = cop_buffer[7];	//   abort code (MSB)
			   *length = 0;								//   no data received!
				// Return value is abort code!
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error;
			}
			if((cop_buffer[0] & 0xE0) != 0x40) {		// unknown command specifier?
				cop_error = SDOERR_UNKNOWN_SPECIFIER;	//   abort: unknown command specifier
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
			   *length = 0;								//   no data received!
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_FORMAT;
			}
			if((cop_buffer[0] & 0x02) == 0x02) {		// expedited transfer?
				if((cop_buffer[0] & 0x01) == 0x01)
					n = 4 - (short)((cop_buffer[0] & 0x0C) >> 2);
				else
					n = 4;
				memcpy(data, &cop_buffer[4], n < max? n : max);
			   *length = n < max? n : max;				//   data received!!!
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_NOERROR;
			}
			break;
		case CANERR_RX_EMPTY:				// receiver empty:
			if(can_is_timeout()) {						//   time-out occurred?
				cop_error = SDOERR_PROTOCOL_TIMEOUT;	//   abort: time-out
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
			   *length = 0;								//   no data received!
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_TIMEOUT;
			}
			break;
		default:							// other errors:
			cop_error = SDOERR_GENERAL_ERROR;			//   abort: general error
			cop_buffer[0] = 0x80;						//   command specifier
			cop_buffer[1] = LOBYTE(index);				//   multiplexor: index (LSB)
			cop_buffer[2] = HIBYTE(index);				//                index (MSB)
			cop_buffer[3] = (BYTE)(subindex);			//            subindex
			cop_buffer[4] = LOLOBYTE(cop_error);		// abort code (LSB)
			cop_buffer[5] = LOHIBYTE(cop_error);		//  -"-
			cop_buffer[6] = HILOBYTE(cop_error);		//  -"-
			cop_buffer[7] = HIHIBYTE(cop_error);		// abort code (MSB)
		   *length = 0;									//   no data received!
			// Transmit SDO abort and return
			can_transmit(CANBUF_TX, 8, cop_buffer);
			can_delete(CANBUF_TX);
			can_delete(CANBUF_RX);
			return cop_error = rc;
		}
	}	while(rc != CANERR_NOERROR);		// segmented transfer:

	// ---  Upload SDO Segment  ---
	for(*length = 0;;)
	{
		cop_buffer[0] = 0x60 | t;		// client command specifier
		cop_buffer[1] = 0x00;			// reserved: set to 00h
		cop_buffer[2] = 0x00;			//   -"-
		cop_buffer[3] = 0x00;			//   -"-
		cop_buffer[4] = 0x00;			//   -"-
		cop_buffer[5] = 0x00;			//   -"-
		cop_buffer[6] = 0x00;			//   -"-
		cop_buffer[7] = 0x00;			//   -"-
		n = 8;							// 8 bytes to transmit!

		// 5. Transmit the client SDO message
		if((cop_error = can_transmit(CANBUF_TX, n, cop_buffer)) != CANERR_NOERROR) {
			can_delete(CANBUF_TX);
			can_delete(CANBUF_RX);
			return cop_error;
		}
		// 6. Start timer for SDO time-out
		can_start_timer(cop_timeout);

		// 7. Wait until server message is received
		do	{
			switch((rc = can_receive(CANBUF_RX, &n, cop_buffer)))
			{
			case CANERR_NOERROR:			// confirmation:
				if(n != 8) {								// 8 bytes received?
					cop_error = SDOERR_GENERAL_ERROR;		//   abort: general error
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				   *length = 0;								//   no data received!
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_LENGTH;
				}
				if((cop_buffer[0] & 0xE0) == 0x80) {// SDO abort received?
					LOLOBYTE(cop_error) = cop_buffer[4];	//   abort code (LSB)
					LOHIBYTE(cop_error) = cop_buffer[5];	//    -"-
					HILOBYTE(cop_error) = cop_buffer[6];	//    -"-
					HIHIBYTE(cop_error) = cop_buffer[7];	//   abort code (MSB)
				   *length = 0;								//   no data received!
					// Return value is abort code!
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error;
				}
				if((cop_buffer[0] & 0xE0) != 0x00) {		// unknown command specifier?
					cop_error = SDOERR_UNKNOWN_SPECIFIER;	//   abort: unknown command specifier
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				   *length = 0;								//   no data received!
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_FORMAT;
				}
				if((cop_buffer[0] & 0x10) != t) {			// toggle bit not altered?
					cop_error = SDOERR_WRONG_TOGGLEBIT;		//   abort: toggle bit not altered
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//  abort code (MSB)
				   *length = 0;								//   no data received!
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_FORMAT;
				}
				if((cop_buffer[0] & 0x0E) != 0x00)			// number of segment data bytes
					n = 7 - (int)((cop_buffer[0] & 0x0E) >> 1);
				else
					n = 7;
				if(max - *length > 0)						// copy segment data if space
					memcpy(&data[*length], &cop_buffer[1], *length + n < max? n : max - *length);
			   *length += n;
				if((cop_buffer[0] & 0x01) == 0x01) {		// no more segments?
					if(*length > max)
					   *length = max;						//   truncate to buffer size!
					if(*length < max)
						data[*length] = '\0';				//   for zero-closed strings!
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_NOERROR;
				}
				break;
			case CANERR_RX_EMPTY:				// receiver empty:
				if(can_is_timeout()) {						//   time-out occurred?
					cop_error = SDOERR_PROTOCOL_TIMEOUT;	//   abort: time-out
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				   *length = 0;								//   no data received!
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_TIMEOUT;
				}
				break;
			default:							// other errors:
				cop_error = SDOERR_GENERAL_ERROR;			//   abort: general error
				cop_buffer[0] = 0x80;						//   command specifier
				cop_buffer[1] = LOBYTE(index);				//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);				//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);			//            subindex
				cop_buffer[4] = LOLOBYTE(cop_error);		// abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);		//  -"-
				cop_buffer[6] = HILOBYTE(cop_error);		//  -"-
				cop_buffer[7] = HIHIBYTE(cop_error);		// abort code (MSB)
			   *length = 0;									//   no data received!
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = rc;
			}
		}	while(rc != CANERR_NOERROR);

		t = t? 0x00 : 0x10;				// alternate toggle bit!
	}	
}
Esempio n. 17
0
static LONG sdo_segmented(BYTE node_id, WORD index, BYTE subindex, SHORT length, BYTE *data)
{
	short n, i;							// data length code
	short rc;							// return value
	short t = 0;						// toggle bit
	
	// ---  Initiate SDO Download  ---
	cop_buffer[0] = (BYTE)0x21;			// client command specifier
	cop_buffer[1] = LOBYTE(index);		// multiplexor: index (LSB)
	cop_buffer[2] = HIBYTE(index);		//              index (MSB)
	cop_buffer[3] = (BYTE)(subindex);	//              subindex
	cop_buffer[4] = LOBYTE(length);		// number of data bytes (LSB)
	cop_buffer[5] = HIBYTE(length);		//  -"-
	cop_buffer[6] = (BYTE)0x00;			//  -"-
	cop_buffer[7] = (BYTE)0x00;			// number of data bytes (MSB)
	n = 8;								// 8 bytes to transmit!

	// 1. Configure transmit message object for client SDO
	if((cop_error = can_config(CANBUF_TX, SDO_CLIENT + node_id, CANMSG_TRANSMIT)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		return cop_error;
	}
	// 2. Configure receive message object for server SDO 
	if((cop_error = can_config(CANBUF_RX, SDO_SERVER + node_id, CANMSG_RECEIVE)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		can_delete(CANBUF_RX);
		return cop_error;
	}
	// 2. Transmit the client SDO message
	if((cop_error = can_transmit(CANBUF_TX, n, cop_buffer)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		can_delete(CANBUF_RX);
		return cop_error;
	}
	// 3. Start timer for SDO time-out
	can_start_timer(cop_timeout);

	// 4. Wait until server message is received
	do	{
		switch((rc = can_receive(CANBUF_RX, &n, cop_buffer)))
		{
		case CANERR_NOERROR:			// confirmation:
			if(n != 8) {								// 8 bytes received?
				cop_error = SDOERR_GENERAL_ERROR;		//   abort: general error
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_LENGTH;
			}
			if((cop_buffer[1] != LOBYTE(index)) ||		// multiplexor? index (LSB)
			   (cop_buffer[2] != HIBYTE(index)) ||		//              index (MSB)
			   (cop_buffer[3] != (BYTE)(subindex))) {	//              subindex
				rc = COPERR_FORMAT;
				break;
			}
			if((cop_buffer[0] & 0xFF) == 0x80) {		// SDO abort received?
				LOLOBYTE(cop_error) = cop_buffer[4];	//   abort code (LSB)
				LOHIBYTE(cop_error) = cop_buffer[5];	//    -"-
				HILOBYTE(cop_error) = cop_buffer[6];	//    -"-
				HIHIBYTE(cop_error) = cop_buffer[7];	//   abort code (MSB)
				// Return value is abort code!
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error;
			}
			if((cop_buffer[0] & 0xFF) != 0x60) {		// unknown command specifier?
				cop_error = SDOERR_UNKNOWN_SPECIFIER;	//   abort: unknown command specifier
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_FORMAT;
			}
		case CANERR_RX_EMPTY:			// receiver empty:
			if(can_is_timeout()) {						//   time-out occurred?
				cop_error = SDOERR_PROTOCOL_TIMEOUT;	//   abort: time-out
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_TIMEOUT;
			}
			break;
		default:						// other errors:
			cop_error = SDOERR_GENERAL_ERROR;			//   abort: general error
			cop_buffer[0] = 0x80;						//   command specifier
			cop_buffer[1] = LOBYTE(index);				//   multiplexor: index (LSB)
			cop_buffer[2] = HIBYTE(index);				//                index (MSB)
			cop_buffer[3] = (BYTE)(subindex);			//            subindex
			cop_buffer[4] = LOLOBYTE(cop_error);		// abort code (LSB)
			cop_buffer[5] = LOHIBYTE(cop_error);		//  -"-
			cop_buffer[6] = HILOBYTE(cop_error);		//  -"-
			cop_buffer[7] = HIHIBYTE(cop_error);		// abort code (MSB)
			// Transmit SDO abort and return
			can_transmit(CANBUF_TX, 8, cop_buffer);
			can_delete(CANBUF_TX);
			can_delete(CANBUF_RX);
			return cop_error = rc;
		}
	}	while(rc != CANERR_NOERROR);

	// ---  Download SDO Segment  ---
	for(i = 0;;)
	{
		if(length <= 7)					// bytes that does not contain data
			n = 7 - length;
		else							// no segment size indicated
			n = 0;
		cop_buffer[0] = (BYTE)(n << 1);	// client command specifier
		memset(&cop_buffer[1], 0x00, 7);// clear data buffer
		memcpy(&cop_buffer[1], &data[i], 7 - n);// copy segment data
		length -= 7 - n;				// remaining number of bytes
		i	   += 7 - n;				// index to remainung bytes
		cop_buffer[0]|= length? 0x00 : 0x01;// last segment to transmit
		cop_buffer[0]|= t;				// toggle bit
		n = 8;							// 8 bytes to transmit!

		// 5. Transmit the client SDO message
		if((cop_error = can_transmit(CANBUF_TX, n, cop_buffer)) != CANERR_NOERROR) {
			can_delete(CANBUF_TX);
			can_delete(CANBUF_RX);
			return cop_error;
		}
		// 6. Start timer for SDO time-out
		can_start_timer(cop_timeout);

		// 7. Wait until server message is received
		do	{
			switch((rc = can_receive(CANBUF_RX, &n, cop_buffer)))
			{
			case CANERR_NOERROR:			// confirmation:
				if(n != 8) {								// 8 bytes received?
					cop_error = SDOERR_GENERAL_ERROR;		//   abort: general error
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_LENGTH;
				}
				if((cop_buffer[0] & 0xE0) == 0x80) {		// SDO abort received?
					LOLOBYTE(cop_error) = cop_buffer[4];	//   abort code (LSB)
					LOHIBYTE(cop_error) = cop_buffer[5];	//    -"-
					HILOBYTE(cop_error) = cop_buffer[6];	//    -"-
					HIHIBYTE(cop_error) = cop_buffer[7];	//   abort code (MSB)
					// Return value is abort code!
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error;
				}
				if((cop_buffer[0] & 0xE0) != 0x20) {		// unknown command specifier?
					cop_error = SDOERR_UNKNOWN_SPECIFIER;	//   abort: unknown command specifier
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_FORMAT;
				}
				if((cop_buffer[0] & 0x10) != t) {			// toggle bit not altered?
					cop_error = SDOERR_WRONG_TOGGLEBIT;		//   abort: toggle bit not altered
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_FORMAT;
				}
				if(length == 0)	{							// all data tranmitted?
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_NOERROR;
				}
			case CANERR_RX_EMPTY:			// receiver empty:
				if(can_is_timeout()) {						//   time-out occurred?
					cop_error = SDOERR_PROTOCOL_TIMEOUT;	//   abort: time-out
					cop_buffer[0] = 0x80;					//   command specifier
					cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
					cop_buffer[2] = HIBYTE(index);			//                index (MSB)
					cop_buffer[3] = (BYTE)(subindex);		//                subindex
					cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
					cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
					cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
					cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
					// Transmit SDO abort and return
					can_transmit(CANBUF_TX, 8, cop_buffer);
					can_delete(CANBUF_TX);
					can_delete(CANBUF_RX);
					return cop_error = COPERR_TIMEOUT;
				}
				break;
			default:						// other errors:
				cop_error = SDOERR_GENERAL_ERROR;			//   abort: general error
				cop_buffer[0] = 0x80;						//   command specifier
				cop_buffer[1] = LOBYTE(index);				//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);				//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);			//            subindex
				cop_buffer[4] = LOLOBYTE(cop_error);		// abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);		//  -"-
				cop_buffer[6] = HILOBYTE(cop_error);		//  -"-
				cop_buffer[7] = HIHIBYTE(cop_error);		// abort code (MSB)
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = rc;
			}
		}	while(rc != CANERR_NOERROR);

		t = t? 0x00 : 0x10;				// alternate toggle bit!
	}
}
Esempio n. 18
0
static LONG sdo_expedited(BYTE node_id, WORD index, BYTE subindex, SHORT length, BYTE *data)
{
	short n;							// data length code
	short rc;							// return value
	
	// ---  Expedited SDO Download  ---
	cop_buffer[0]  = (BYTE)0x23;		// client command specifier
	cop_buffer[0] |= (BYTE)((4 - length) << 2);
	cop_buffer[1]  = LOBYTE(index);		// multiplexor: index (LSB)
	cop_buffer[2]  = HIBYTE(index);		//              index (MSB)
	cop_buffer[3]  = (BYTE)(subindex);	//              subindex
	memset(&cop_buffer[4],0x00,4);		// clear data buffer
	memcpy(&cop_buffer[4],data,length);	// copy data bytes
	n = 8;								// 8 bytes to transmit!

	// 1. Configure transmit message object for client SDO
	if((cop_error = can_config(CANBUF_TX, SDO_CLIENT + node_id, CANMSG_TRANSMIT)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		return cop_error;
	}
	// 2. Configure receive message object for server SDO 
	if((cop_error = can_config(CANBUF_RX, SDO_SERVER + node_id, CANMSG_RECEIVE)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		can_delete(CANBUF_RX);
		return cop_error;
	}
	// 2. Transmit the client SDO message
	if((cop_error = can_transmit(CANBUF_TX, n, cop_buffer)) != CANERR_NOERROR) {
		can_delete(CANBUF_TX);
		can_delete(CANBUF_RX);
		return cop_error;
	}
	// 3. Start timer for SDO time-out
	can_start_timer(cop_timeout);

	// 4. Wait until server message is received
	do	{
		switch((rc = can_receive(CANBUF_RX, &n, cop_buffer)))
		{
		case CANERR_NOERROR:			// confirmation:
			if(n != 8) {								// 8 bytes received?
				cop_error = SDOERR_GENERAL_ERROR;		//   abort: general error
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_LENGTH;
			}
			if((cop_buffer[1] != LOBYTE(index)) ||		// multiplexor? index (LSB)
			   (cop_buffer[2] != HIBYTE(index)) ||		//              index (MSB)
			   (cop_buffer[3] != (BYTE)(subindex))) {	//              subindex
				rc = COPERR_FORMAT;
				break;
			}
			if((cop_buffer[0] & 0xFF) == 0x80) {		// SDO abort received?
				LOLOBYTE(cop_error) = cop_buffer[4];	//   abort code (LSB)
				LOHIBYTE(cop_error) = cop_buffer[5];	//    -"-
				HILOBYTE(cop_error) = cop_buffer[6];	//    -"-
				HIHIBYTE(cop_error) = cop_buffer[7];	//   abort code (MSB)
				// Return value is abort code!
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error;
			}
			if((cop_buffer[0] & 0xFF) != 0x60) {		// unknown command specifier?
				cop_error = SDOERR_UNKNOWN_SPECIFIER;	//   abort: unknown command specifier
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_FORMAT;
			}
			else {										// success: data written!
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_NOERROR;
			}
		case CANERR_RX_EMPTY:			// receiver empty:
			if(can_is_timeout()) {						//   time-out occurred?
				cop_error = SDOERR_PROTOCOL_TIMEOUT;	//   abort: time-out
				cop_buffer[0] = 0x80;					//   command specifier
				cop_buffer[1] = LOBYTE(index);			//   multiplexor: index (LSB)
				cop_buffer[2] = HIBYTE(index);			//                index (MSB)
				cop_buffer[3] = (BYTE)(subindex);		//                subindex
				cop_buffer[4] = LOLOBYTE(cop_error);	//   abort code (LSB)
				cop_buffer[5] = LOHIBYTE(cop_error);	//    -"-
				cop_buffer[6] = HILOBYTE(cop_error);	//    -"-
				cop_buffer[7] = HIHIBYTE(cop_error);	//   abort code (MSB)
				// Transmit SDO abort and return
				can_transmit(CANBUF_TX, 8, cop_buffer);
				can_delete(CANBUF_TX);
				can_delete(CANBUF_RX);
				return cop_error = COPERR_TIMEOUT;
			}
			break;
		default:						// other errors:
			cop_error = SDOERR_GENERAL_ERROR;			//   abort: general error
			cop_buffer[0] = 0x80;						//   command specifier
			cop_buffer[1] = LOBYTE(index);				//   multiplexor: index (LSB)
			cop_buffer[2] = HIBYTE(index);				//                index (MSB)
			cop_buffer[3] = (BYTE)(subindex);			//            subindex
			cop_buffer[4] = LOLOBYTE(cop_error);		// abort code (LSB)
			cop_buffer[5] = LOHIBYTE(cop_error);		//  -"-
			cop_buffer[6] = HILOBYTE(cop_error);		//  -"-
			cop_buffer[7] = HIHIBYTE(cop_error);		// abort code (MSB)
			// Transmit SDO abort and return
			can_transmit(CANBUF_TX, 8, cop_buffer);
			can_delete(CANBUF_TX);
			can_delete(CANBUF_RX);
			return cop_error = rc;
		}
	}	while(1);						// "the torture never stops!"
}
Esempio n. 19
0
void can_tx_left_ankle_angle(void){can_transmit(&tx_fd_left_ankle_angle);}
Esempio n. 20
0
void can_tx_max_exec_time(void){can_transmit(&tx_fd_max_exec_time);}
Esempio n. 21
0
void can_tx_status(void){can_transmit(&tx_fd_status);}
Esempio n. 22
0
//Wrapper functions for calling CAN transmit from the scheduler
void can_tx_left_ankle_rate(void){can_transmit(&tx_fd_left_ankle_rate);}
Esempio n. 23
0
/*===========================================================================
 *===========================================================================*/
void
display_adapter(struct mg_connection *c, const struct mg_request_info *ri, void *user_data)
{
	struct Squirrel *squirrel = (struct Squirrel *)user_data;
	char adapter_name[256];
	char description[256];
	unsigned exists;
	const char *driver = "";
	unsigned interface_channel = 0;

	pixie_enter_critical_section(squirrel->cs);

	if (memcmp(ri->uri, "/adapter/", 9) != 0) {
		mg_printf(c, "404 Not Found\r\nConnection: closed\r\n\r\n");
		goto _return;
	} else
		sprintf_s(adapter_name, sizeof(adapter_name), "%s", ri->uri+9);

	if (strlen(adapter_name) > 5 && memcmp(adapter_name+strlen(adapter_name)-5, ".html", 5) == 0)
		adapter_name[strlen(adapter_name)-5] = '\0';
	if (strlen(adapter_name) > 7 && memcmp(adapter_name, "airpcap", 7) == 0 && strlen(adapter_name) < sizeof(adapter_name)-5) {
		memmove(adapter_name+4, adapter_name, strlen(adapter_name)+1);
		memcpy(adapter_name, "\\\\.\\", 4);
	}

	exists = adapter_description(adapter_name, description, sizeof(description));
	if (!exists) {
		mg_printf(c, "404 Not Found\r\nConnection: closed\r\n\r\n");
		goto _return;
	}
	if (strstr(adapter_name, "\\airpcap")) {
		driver = "airpcap";
	} else {
		driver = "ndis";
	}

	mg_headers_ok(c, "text/html");
	X(c, "Connection: close\r\n");
	X(c, "\r\n");

	//X(c, "<!DOCTYPE HTML PUBLIC \"-//W3C//DTD HTML 4.01//EN\" \"http://www.w3.org/TR/html4/strict.dtd\">\r\n");
	X(c,"<html>\n");
	X(c,"<head>\n");
	X(c," <title>Squirrel WiFi monitor / Adapter</title>\n");
	X(c," <link rel=\"stylesheet\" type=\"text/css\" href=\"../squirrel.css\" />\n");
	X(c," <link rel=\"Shortcut Icon\" href=\"../favicon.ico\" type=\"image/x-icon\">\n");
	X(c,"</head>\n");
	X(c,"<body>\n");

	display_topmenu(c, ri, user_data, 0);

	/*
	 * Do any necessary changes
	 */
	{
		char *status = mg_get_var(c, "status");
		char *channel = mg_get_var(c, "channel");

		if (status && channel) {
			unsigned is_running = squirrel_get_interface_status(squirrel, adapter_name, &interface_channel);
			unsigned new_channel;
			if (strcmp(channel, "scan") == 0)
				new_channel = (unsigned)-1;
			else if (isdigit(channel[0]))
				new_channel = atoi(channel);
			else
				new_channel = 0;

			if (is_running && strcmp(status, "monitor") != 0) {
				/* Turn off the adapter */
				squirrel_set_interface_status(squirrel, adapter_name, 0, 0);
				X(c, "<b>Turned off adapter</b>\n");
			} else if (!is_running && strcmp(status, "monitor") == 0) {
				launch_thread(squirrel, adapter_name);
				squirrel_set_interface_status(squirrel, adapter_name, 1, new_channel);
				X(c, "<b>Turned on adapter, channel %u</b>\n", new_channel);
			} else if (is_running && interface_channel != new_channel) {
				squirrel_set_interface_status(squirrel, adapter_name, 1, new_channel);
				X(c, "<b>Changed channel to %u</b>\n", new_channel);
			} else
				X(c, "<b>Nothing changed</b>\n");
		}
		if (status)
			free(status);
		if (channel)
			free(channel);
	}

	X(c, "<table class=\"adapter\">\n");
	X(c, "  <tr><th>Adapter:</th><td>%s</td></tr>\n", adapter_name);
	X(c, "  <tr><th>Description:</th><td>%s</td></tr>\n", description);
	X(c, "  <tr><th>Driver:</th><td>%s</td></tr>\n", driver);
	X(c, "  <tr><th>Monitor Mode:</th><td>%s</td></tr>\n", can_monitor_mode(adapter_name)?"yes":"no");
	X(c, "  <tr><th>Can Transmit:</th><td>%s</td></tr>\n", can_transmit(adapter_name)?"yes":"no");


	if (squirrel_get_interface_status(squirrel, adapter_name, &interface_channel)) {
		X(c, "  <tr><th>Status:</th><td>%s</td></tr>\n", "monitoring");
		if (interface_channel == 0)
			X(c, "  <tr><th>Channel:</th><td>%s</td></tr>\n", "");
		else if (interface_channel == (unsigned)-1)
			X(c, "  <tr><th>Channel:</th><td>%s</td></tr>\n", "scan");
		else
			X(c, "  <tr><th>Channel:</th><td>%u</td></tr>\n", interface_channel);

	} else {
		X(c, "  <tr><th>Status:</th><td>%s</td></tr>\n", "off");
		X(c, "  <tr><th>Channel:</th><td>%s</td></tr>\n", "");
	}
	X(c, "</table>\n");

	X(c, "<hr/>\n");
	X(c, "<form action=\"%s.html\">\n", adapter_name);
	X(c, " <input type=\"radio\" name=\"status\" value=\"monitor\" /> Monitor<br/>\n");
	X(c, " <input type=\"radio\" name=\"status\" value=\"off\" /> Off<br/>\n");
	X(c, " Channel: <input type=\"text\" name=\"channel\" value=\"scan\"/><br/>\n");
	X(c, " <input type=\"submit\" value=\"Submit\">\n");
	X(c, "</form>\n");

_return:
	pixie_leave_critical_section(squirrel->cs);
}
Esempio n. 24
0
void can_tx_color_red(void){can_transmit(&tx_fd_color_red);}
Esempio n. 25
0
void can_tx_color_blue(void){can_transmit(&tx_fd_color_blue);}
Esempio n. 26
0
void can_tx_color_white(void){can_transmit(&tx_fd_color_white);}
Esempio n. 27
0
void can_tx_color_green(void){can_transmit(&tx_fd_color_green);}
Esempio n. 28
0
File: em-stop.c Progetto: GBert/misc
void sys_tick_handler(void) {
    static uint8_t data[5] = { 0, 0, 0, 0, 0 };

    /* We call this handler every 1ms so every 1ms = 0.001s
     * resulting in 1Hz message rate.
     */

    /* Transmit CAN frame. */
    counter++;

    if (gpio_port_read(GPIO_PORT_B_BASE) && (1 << 6)) {
	/* if status changed send command */
	if (status == 1) {
	    data[4] = 0;
	    can_transmit(CAN1, 0x0000fffe, true, false, 5, data);
	}
	status = 0;
    } else if (!(gpio_port_read(GPIO_PORT_B_BASE) && (1 << 7))) {
	/* if status changed send command */
	if (status == 0) {
	    data[4] = 1;
	    can_transmit(CAN1, 0x0000fffe, true, false, 5, data);
	}
	status = 1;
    }
#if 1
    switch (counter) {
    case 125:
	gpio_clear(GPIOB, GPIO3);
	break;
    case 250:
	gpio_set(GPIOB, GPIO3);
	break;
    case 375:
	gpio_clear(GPIOB, GPIO3);
	break;
    case 500:
	gpio_set(GPIOB, GPIO4);
	break;
    case 1000:
	counter = 0;
	break;
    default:
	break;
    }
#else
    if (counter == 1000) {
	counter = 0;
	if (status) {
	    data[4] = 1;
	} else {
	    data[4] = 0;
	}

	if (can_transmit(CAN1, 0x0000fffe,	/* (EX/ST)ID: CAN ID */
			 true,	/* IDE: CAN ID extended? */
			 false,	/* RTR: Request transmit? */
			 5,	/* DLC: Data length */
			 data) == -1) {
	    gpio_set(GPIOC, GPIO13);	/* LED green off */
	}
    }
#endif
}
void vControl ( void *pvParameters )
{
	portTickType xLastWakeTime;
	signed char valx, valy;
	unsigned char ls, rs, lb, rb;

	can_frame_t out_frame;
	can_frame_t in_frame;
	out_frame.id = 1;
	out_frame.dlc = 6;

	xLastWakeTime = xTaskGetTickCount ();

	/* Button init */
	buttons_init ();

	/* FSM init */
	fsm_init ();

	/* CAN init */
	can_init ();

	/* ADC init */
	adc_init ( ctrlNUM_ADC_VALUES );

	/* Touch init */
	touch_init ( 30, 30, 30, 30 );

	while (1)
	{
		vTaskDelayUntil ( &xLastWakeTime, ctrlTASK_FREQUENCY );

		if ( adc_conversion_complete () == pdTRUE )
		{
			adc_disable ();
			adc_get_value ( &valx, 0 );
			adc_get_value ( &valy, 0 );
			touch_measure ( &ls, &rs, &lb, &rb );

			out_frame.data[0] = valx;
			out_frame.data[1] = valy;
			out_frame.data[2] = ls;
			out_frame.data[3] = rs;
			out_frame.data[4] = lb;
			out_frame.data[5] = rb;

			if (fsm_get_state() == ST_PLAY)
			{
				can_transmit (&out_frame);
			}
						
			can_receive (&in_frame, 0);

			if (in_frame.data[0] == GAME_SENSOR_TRIGGERED)
			{
				// TODO: set triggered state
				fsm_event_t *event = pvPortMalloc (sizeof (fsm_event_t));
				event->type = EV_STOP;
				event->ptr = NULL;
				fsm_event_put (event, portMAX_DELAY);
				in_frame.data[0] = 0;
			}
			else if (in_frame.data[0] == GAME_SENSOR_CLEARED)
			{
				// TODO: set cleared state
				in_frame.data[0] = 0;
			}

			adc_enable ();
			adc_conversion_start ();
		}

		fsm_update ();
	}
}