Super Vision
/
mbed_sv_firmware
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Dependencies: MODSERIAL USBDevice mbed-rtos mbed
Fork of
mbed_sv_firmware_mt
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Super Vision
Diff: main.cpp
- Revision:
- 4:13e3e375c0d3
- Parent:
- 3:e8cc286f9b2e
- Child:
- 5:e77529f7ede3
--- a/main.cpp Tue Jan 20 01:09:41 2015 +0000
+++ b/main.cpp Tue Jan 20 22:26:26 2015 +0000
@@ -17,6 +17,10 @@
#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
+#define ERR_I2C_NOT_WRITEABLE 6 // UART has no buffer space
+#define ERR_I2C_NO_TX_ENDMARK 7 // message for UART has no 0x7E end-mark
+#define ERR_I2C_NO_RX_ENDMARK 8 // message received from UART has no end-mark
+#define ERR_NOT_IMPLEMENTED 255 // method has not yet been implemented
// I2C addresses
@@ -46,8 +50,7 @@
uint8_t cdc_buffer_tx[32];
uint8_t uart_buffer_rx[32]; // buffers for uart (RFID-FE board)
uint8_t uart_buffer_tx[32];
-uint8_t i2c_buffer_rx[32]; // buffers for I2C devices - Proximity sensor and EEPROM
-uint8_t i2c_buffer_tx[32];
+char i2c_buffer[264]; // buffer for I2C devices - Proximity sensor and EEPROM - up to 256 bytes data payload for EEPROM, up to 4 for proximity
int i, j; // index variables
int status = 0x00; // return value
@@ -77,6 +80,9 @@
return 0;
}
+/*
+RFID messages are as defined in the RFID-FE manual.
+ */
int rfid_msg(void)
{
bool end_mark = FALSE;
@@ -127,54 +133,49 @@
}
-int prox_msg()
+/*
+I2C-prox messages = 0xCC, r/w, number of data bytes, index (2 bytes), data bytes, 0x7E, 0xXX, 0xXX - last two are fillers where CRC goes for RFID
+
+Multiple registers can be read or written with single prox_msg_rd() or prox_msg_wr(). Location address increments for each byte.
+ */
+
+int prox_msg_wr() // write proximity I2C register
{
- bool end_mark = FALSE;
- int i;
- uint8_t crcCount = sizeof(i2c_buffer_tx); // use tx buffer size to start
-
- i2c.txBufferFlush(); // clear out UART buffers
- i2c.rxBufferFlush();
+ int i2c_err;
+ i2c_err = i2c.write(PROX, &i2c_buffer[3], i2c_buffer[2] + 2, 0);// I2C Address, pointer to buffer, number of bytes (for index + data), stop at end.
+ return i2c_err; // 0 = ACK received, 1 = NAK/failure
+}
- 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;
- }
- }
+int prox_msg_rd()
+{
+ int i2c_err;
+ i2c_err = i2c.write(PROX, &i2c_buffer[3], 2, 1); // I2C Address, pointer to buffer (just the index), index, number of bytes (2 for index), no stop at end.
+ i2c_err |= i2c.read(PROX, &i2c_buffer[5], i2c_buffer[2], 0); // I2C Address, pointer to buffer (just the data), number of data bytes, stop at end.
+ return i2c_err; // 0 = ACK received, 1 = NAK/failure
+}
+
+
+/*
+I2C-EEPROM messages = 0xEE, r/w, number of data bytes, block, address, data bytes, 0x7E, 0xXX, 0xXX - last two are fillers where CRC goes for RFID
+
+Multiple registers can be read or written with single eeprom_msg_rd() or eeprom_msg_wr(). Location address increments for each byte.
+This practically the the same as the proximity calls, except the index/location is only one byte and the block select is part of the I2C address byte.
+ */
+
+int eeprom_msg_wr() // write proximity I2C register
+{
+ int i2c_err;
+ i2c_err = i2c.write((EEPROM || i2c_buffer[3]), &i2c_buffer[4], i2c_buffer[2] + 1, 0); // I2C Address & block select, pointer to buffer, number of bytes (for address + data), stop at end.
+ while (!i2c.write(EEPROM || i2c_buffer[3])); // wait until write is done (EEPROM will ACK = 1 for single byte i2c.write)
+ return i2c_err; // 0 = ACK received, 1 = NAK/failure
+}
- end_mark = FALSE;
- //wait(0.5); // debug
- while(!uart.readable()); // 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;
- return ERR_NONE;
+int eeprom_msg_rd()
+{
+ int i2c_err;
+ i2c_err = i2c.write((EEPROM || i2c_buffer[3]), &i2c_buffer[4], 1, 1); // I2C Address & block select, pointer to buffer (just the index), index, number of bytes (for address + data), no stop at end.
+ i2c_err |= i2c.read((EEPROM || i2c_buffer[3]), &i2c_buffer[5], i2c_buffer[2], 0); // I2C Address & block select, pointer to buffer (just the data), number of data bytes, stop at end.
+ return i2c_err; // 0 = ACK received, 1 = NAK/failure
}
int gpio_msg()
@@ -182,11 +183,6 @@
return ERR_NONE;
}
-int eeprom_msg() // eeprom to be implemented along with next hardware prototype
-{
- return ERR_NONE;
-}
-
int main()
{
// initialize everything
@@ -238,7 +234,7 @@
for (i = 0; i < sizeof(cdc_buffer_tx); i++)
{
- cdc.putc(), cdc_buffer_tx[i]); // send message back to PC
+ cdc.putc(cdc_buffer_tx[i]); // send message back to PC
if (cdc_buffer_tx[i] == 0x7E) // check for rfid end mark in outbound message
{
@@ -252,24 +248,26 @@
}
}
break;
- case 0xCC: // Proximity Sensor
- for (i = 0; i < sizeof(cdc_buffer_rx); i++)
+ case 0xCC:
+ //I2C-prox messages = 0xCC, r/w, number of data bytes, index, data bytes, 0x7E, 0xXX, 0xXX - last two are fillers where CRC goes for RFID // Proximity Sensor
+ for (i = 0; i < sizeof(cdc_buffer_rx); i++)
{
- i2c_buffer_tx[i] = cdc_buffer_rx[i + 1]; // copy USB message to buffer for I2C
+ i2c_buffer[i] = cdc_buffer_rx[i]; // copy USB message to buffer for I2C
}
- status = prox_msg(); // send buffer to RFID and get response according to RFID board
+ if (i2c_buffer[1] == 1) // I2C read = 1
+ status = prox_msg_rd(); // read the requested data
+ else if (i2c_buffer[1] == 0) // I2C write = 0
+ status = prox_msg_wr(); // send buffer to proximity sensor and get response
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_buffer_tx[i] = i2c_buffer[i]; // copy prox response back to USB buffer
}
- //cdc.printf("\n\rRFID Response: "); // debug
-
for (i = 0; i < sizeof(cdc_buffer_tx); i++)
{
- cdc.putc(), cdc_buffer_tx[i]); // send message back to PC
+ cdc.putc(cdc_buffer_tx[i]); // send message back to PC
if (cdc_buffer_tx[i] == 0x7E) // check for rfid end mark in outbound message
{
@@ -282,14 +280,47 @@
break;
}
}
-
break;
case 0xDD: // GPIO (LEDs and RFID-FE control
gpio_msg();
break;
case 0xEE: // Read/write EEPROM
- eeprom_msg();
- break;
+/*
+I2C-EEPROM messages = 0xEE, r/w, number of data bytes, block, address, data bytes, 0x7E, 0xXX, 0xXX - last two are fillers where CRC goes for RFID
+
+Multiple registers can be read or written with single eeprom_msg_rd() or eeprom_msg_wr(). Location address increments for each byte.
+This practically the the same as the proximity calls, except the index/location is only one byte and the block select is part of the I2C address byte.
+ */
+ for (i = 0; i < sizeof(cdc_buffer_rx); i++)
+ {
+ i2c_buffer[i] = cdc_buffer_rx[i]; // copy USB message to buffer for I2C
+ }
+
+ if (i2c_buffer[1] == 1) // I2C read = 1
+ status = eeprom_msg_rd(); // read the requested data
+ else if (i2c_buffer[1] == 0) // I2C write = 0
+ status = eeprom_msg_wr(); // write the eeprom location
+
+ for (i = 0; i < sizeof(cdc_buffer_tx); i++)
+ {
+ cdc_buffer_tx[i] = i2c_buffer[i]; // copy prox response back to USB buffer
+ }
+
+ for (i = 0; i < sizeof(cdc_buffer_tx); i++)
+ {
+ cdc.putc(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;
default:
return ERR_CDC_BAD_CMD;
}