Super Vision
/
mbed_sv_firmware
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Dependencies: MODSERIAL USBDevice mbed-rtos mbed
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mbed_sv_firmware_mt
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Super Vision
main.cpp
- Committer:
- bob_tpc
- Date:
- 2015-01-19
- Revision:
- 1:bd988d267998
- Parent:
- 0:8604e9cc07f2
- Child:
- 2:efaf8aee55df
File content as of revision 1:bd988d267998:
#include "mbed.h"
#include "USBSerial.h"
#include "MODSERIAL.h"
#include "InterruptIn.h"
// Constants
#define LEDON 0 // Low active for LEDs - turns LED on
#define LEDOFF 1 // Low active for LEDs - turns LED off
#define TRUE 1
#define FALSE 0
// Error return values
#define ERR_NONE 0 // Success
#define ERR_CDC_BAD_CMD 1 // First byte of PC to USB board needs to be 0xBB, 0xCC, 0xDD or 0xEE;
#define ERR_CDC_NO_TX_ENDMARK 2 // message for no endmark on message to PC
#define ERR_UART_NOT_WRITEABLE 3 // UART has no buffer space
#define ERR_UART_NO_TX_ENDMARK 4 // message for UART has no 0x7E end-mark
#define ERR_UART_NO_RX_ENDMARK 5 // message received from UART has no end-mark
// I2C addresses
#define PROX (0x29 << 1) // default I2C address of VL6180X, shift into upper 7 bits
#define EEPROM (0xA0) // default I2C address of EEPROM, already shifted
// UART-RFID baud rate
#define RFIDBAUD 115200 // RFID-FE board default rate = 115.2Kbps
// Peripherals
USBSerial cdc; // CDC Class USB<>Serial adapter. Needs custom INF, but uses existing Windows drivers.
MODSERIAL uart(PTA2, PTA1); // UART port connected to RFID-FE board
I2C i2c(PTB1, PTB0); // I2C port connected to VL6180X and EEPROM - note addresses above)
// GPIO signals
DigitalOut led_err(PTC1); // Red LED shows error condition (active low)
DigitalOut led_com(PTC2); // Yellow LED shows communication activity (active low)
DigitalOut rfid_int(PTD4); // RFID FE power control (active high)
DigitalOut rfid_isp(PTD5); // RFID FE In-System Programming (active high)
DigitalOut rfid_rst(PTD6); // RFID FE Reset (active high)
DigitalOut rfid_pwr(PTE30); // RFID power switch on USB board (active high for prototype 1, low for all others)
DigitalIn rfid_hot(PTE0); // RFID over-current detection on USB board power switch (active low)
InterruptIn prox_int(PTD7); // Proximity sensor interrupt (active low)
// buffers & variables
uint8_t cdc_buffer_rx[32]; // buffers for cdc (USB-Serial port on PC)
uint8_t cdc_buffer_tx[32];
uint8_t uart_buffer_rx[32]; // buffers for uart (RFID-FE board)
uint8_t uart_buffer_tx[32];
int i, j; // index variables
int status = 0x00; // return value
int prox_irq(void)
{
return 0;
}
int init_periph(void)
{
// Set up peripherals
// RFID
uart.baud(RFIDBAUD); // RFID-FE baud rate
rfid_int = 0; // RFID FE power control (active high)
rfid_isp = 0; // RFID FE In-System Programming (active high)
rfid_rst = 1; // RFID FE Reset (active high)
rfid_pwr = 1; // RFID power switch on USB board (active high for prototype 1, low for all others)
wait(0.25); // wait 1/4 second before...
rfid_rst = 0; // ... taking RFID out of reset
// Prox
return 0;
}
int rfid_msg(void)
{
bool end_mark = FALSE;
int i;
uint8_t crcCount = sizeof(uart_buffer_tx); // use tx buffer size to start
uart.txBufferFlush(); // clear out UART buffers
uart.rxBufferFlush();
for (int i = 0; i < sizeof(uart_buffer_tx); i++)
{
if (!uart.writeable()) return ERR_UART_NOT_WRITEABLE; // if no space in uart, return error
uart.putc(uart_buffer_tx[i]); // send uart message
if (uart_buffer_tx[i] == 0x7E) // check for rfid end mark in outbound message
{
crcCount = 2; // two more bytes for CRC
end_mark = TRUE; // end mark was reached
}
if (crcCount-- == 0) // end of message
{
if (end_mark == FALSE) return ERR_UART_NO_TX_ENDMARK; // no end mark detected
break;
}
}
end_mark = FALSE;
wait(0.5);
while(!uart.readable()) printf("."); // wait for data from rfid
crcCount = sizeof(uart_buffer_rx); // use rx buffer size to start
for (i = 0; i < sizeof(uart_buffer_rx); i++)
{
uart_buffer_rx[i] = uart.getc(); // read a character
// cdc.printf("%d, 0x%X\n\r", i, uart_buffer_rx[i]); // debug
if (uart_buffer_rx[i] == 0x7E) // check for rfid end mark in inbound message
{
crcCount = 2; // two more bytes for crc
end_mark = TRUE; // end mark was reached
}
if (crcCount-- == 0) // end of message
{
if (end_mark == FALSE) return ERR_UART_NO_RX_ENDMARK;
break;
}
}
return ERR_NONE;
}
int prox_msg()
{
return ERR_NONE;
}
int gpio_msg()
{
return ERR_NONE;
}
int eeprom_msg() // eeprom to be implemented along with next hardware prototype
{
return ERR_NONE;
}
int main()
{
// initialize everything
wait(3.0);
init_periph();
cdc.printf("Starting...\n\r");
//while(!cdc.readable()); // spin here until a message comes in from the host PC
bool end_mark = FALSE;
uint8_t crcCount = sizeof(cdc_buffer_rx); // use tx buffer size to start
cdc.printf("\n\rCDC Input: ");
for (i = 0; i < sizeof(cdc_buffer_rx); i++)
{
//cdc_buffer_rx[i] = cdc.getc(); //
cdc.printf("%X, ",cdc_buffer_rx[i]);
if (cdc_buffer_rx[i] == 0x7E) // check for rfid end mark in outbound message
{
crcCount = 2; // two more bytes for CRC
end_mark = TRUE; // end mark was reached
}
if (crcCount-- == 0) // end of message
{
if (end_mark == FALSE) return ERR_UART_NO_TX_ENDMARK; // no end mark detected
break;
}
}
switch(cdc_buffer_rx[0])
{
case 0xBB: // RFID-FE
for (i = 0; i < sizeof(cdc_buffer_rx); i++)
{
uart_buffer_tx[i] = cdc_buffer_rx[i]; // copy USB message to UART for RFID
}
status = rfid_msg(); // send buffer to RFID and get response according to RFID board
for (i = 0; i < sizeof(cdc_buffer_tx); i++)
{
cdc_buffer_tx[i] = uart_buffer_rx[i]; // copy RFID response back to USB buffer
}
cdc.printf("\n\rRFID Response: ");
for (i = 0; i < sizeof(cdc_buffer_tx); i++)
{
cdc.printf("%x, ", cdc_buffer_tx[i]); // send message back to PC
if (cdc_buffer_tx[i] == 0x7E) // check for rfid end mark in outbound message
{
crcCount = 2; // two more bytes for CRC
end_mark = TRUE; // end mark was reached
}
if (crcCount-- == 0) // end of message
{
if (end_mark == FALSE) return ERR_CDC_NO_TX_ENDMARK; // no end mark detected
break;
}
}
break;
case 0xCC: // Proximity Sensor
prox_msg();
break;
case 0xDD: // GPIO (LEDs and RFID-FE control
gpio_msg();
break;
case 0xEE: // Read/write EEPROM
eeprom_msg();
break;
default:
return ERR_CDC_BAD_CMD;
}
}