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#include "maindefs.h"
#include "msg_queues.h"
#include "interrupts.h"
#include "uart.h"
#include "i2c.h"
#include "adc.h"
#include "timers.h"
#include "xbee.h"
#include "led_driver.h"
#include "pwm.h"
#include "delays.h"
#include "pin_interrupts.h"
#include "buffer.h"
#pragma config WDTEN = OFF // Turn off watchdog timer
#pragma config XINST = OFF // Turn off extended instruction set
#pragma config OSC = HSPLL // Use external oscillator (101)
#pragma config PLLDIV = 3 // Set PPL prescaler to 3 (to get 4MHz)
#pragma config CFGPLLEN = ON // Enable PLL on startup
#pragma config PLLSEL = PLL96 // Use 96MHz PLL 4MHz -> 96MHz / 2 = 48MHz
//#pragma config SOSCSEL = HIGH // High Power T1OSC/SOSC circuit selected
#pragma config ADCSEL = BIT12 // 12-bit ADrC
#pragma config IOL1WAY = OFF // IOLOCK bit can be set and cleared as needed
/* ----------- IO Pins -----------
* RA0 - LED Display Latch Enable (PPS)
* RA1 - LED Display CLK (PPS)
* RA2 - LED Display DIN (PPS)
* RA3 - LED Display Output Enable (PPS)
* RA4 - [CANNOT BE USED (VDDCORE/VCAP)]
* RA5 - IR Reciever (PPS)
* RA6 - Oscillator
* RA7 - Oscillator
*
* RC0 - PWM Output (IR) (PPS, Ports B and C only)
* RC1 - PWM Output (IR) (PPS, Ports B and C only)
* RC2 - LED Output (PPS, Ports B and C only)
* RC3 - I2C SCL
* RC4 - I2C SDA
* RC5 - XBee Sleep (PPS)
* RC6 - UART Debug Output
* RC7 - UART Debug Input
*
* RB0 - XBee CTS (PPS)
* RB1 - XBee RTS (PPS)
* RB2 - XBee Tx (PPS)
* RB3 - XBee Rx (PPS)
* RB4 - Button Input (Port B Interrupt on Change)
* RB5 - Button Input (Port B Interrupt on Change)
* RB6 - Button Input (Port B Interrupt on Change)
* RB7 - Button Input (Port B Interrupt on Change)
* ---------------------------- */
#pragma udata umain_1
static unsigned char msgbuffer[MSGLEN + 1];
#pragma udata umain_2
static I2C_DATA i2c_data;
#pragma udata
static XBEE_DATA xbee_data;
static UART_DATA uart_data;
static BUFFER_DATA buffer_data;
void main(void) {
char length;
unsigned char msgtype;
unsigned char i = 0;
unsigned char counter = 0;
enum I2C_STATE i2c_state = I2C_STATE_IDLE;
unsigned char i2c_bytes_to_read = 0;
// Pointers to allow parsing of xbee data from arbitrary byte array
XBEE_RX_AT_COMMAND_RESPONSE_FRAME *frame_at_cmd_response;
XBEE_RX_DATA_PACKET_FRAME *frame_data_packet;
XBEE_RX_DATA_TX_STATUS_FRAME *frame_tx_status;
XBEE_RX_IO_DATA_SAMPLE_FRAME *frame_io_sample;
XBEE_RX_EXPLICIT_COMMAND_FRAME *frame_explicit_cmd;
XBEE_RX_REMOTE_AT_COMMAND_FRAME *frame_remote_at_cmd;
XBEE_RX_ROUTE_RECORD_FRAME *frame_route_record;
XBEE_RX_NODE_IDENTIFICATION_INDICATOR_FRAME *frame_node_identification;
XBEE_RX_MODEM_STATUS_FRAME *frame_modem_status;
XBEE_TX_DATA_PACKET_FRAME *frame_tx_data;
/* --------------------- Oscillator Configuration --------------------- */
// OSCTUNEbits.PLLEN = 1; // Enable 4x PLL
// OSCCONbits.IRCF = 0b111; // Set INTOSC postscaler to 8MHz
OSCCONbits.SCS = 0b00; // Use 96MHz PLL as primary clock source
/* -------------------------------------------------------------------- */
// Set all ports as digial I/O
ANCON0 = 0xFF;
ANCON1 = 0x1F;
uart_init(&uart_data); // Initialize the UART handler code
xbee_init(&xbee_data); // Initialize the XBee handler code
i2c_init(&i2c_data); // Initialize the I2C handler code
buffer_init(&buffer_data);
// adc_init(); // Initialize the ADC
MQ_init(); // Initialize message queues before enabling any interrupts
timers_init(); // Initialize timers
led_driver_init(); // Initialize the driver for the LED display
port_b_int_init(); // Initialze Port B interrupt handler
#ifdef _BASE_STATION
intx_init(); // IR receiver input
#endif
#ifdef _REMOTE
pwm_init(); // Initialize the PWM output driver
#endif
interrupt_enable(); // Enable high-priority interrupts and low-priority interrupts
interrupt_init(); // Initialize the interrupt priorities
// Configure the hardware i2c device as a slave
#ifdef _BASE_STATION
i2c_configure_slave(0x5F);
#endif
#ifdef _REMOTE
i2c_configure_master();
#endif
DBG_PRINT_MAIN("\r\nMain: Program Started\r\n");
// Loop and process recieved messages from interrupts
while (1) {
// Call a routine that blocks until either message queues are not empty
MQ_wait_on_incoming_msg_queues();
// Process high priority message queue
length = MQ_recvmsg_ToMainFromHigh(MSGLEN, &msgtype, (void *) msgbuffer);
if (length < 0) {
// No message, check the error code to see if it is concern
if (length != MSG_QUEUE_EMPTY) {
DBG_PRINT_MAIN("Main: (ERROR) Bad high priority receive, code = %d\r\n", length);
}
} else {
switch (msgtype) {
/* --- I2C Message Handlers ----------------------------------*/
case MSGTYPE_OVERRUN:
DBG_PRINT_MAIN("Main: (ERROR) UART overrun detected, type = %d\r\n", msgtype);
break;
case MSGTYPE_I2C_DBG:
DBG_PRINT_MAIN("Main: I2C Dbg Data Recieved: ");
for (i = 0; i < length; i++) {
DBG_PRINT_MAIN("%X ", msgbuffer[i]);
}
DBG_PRINT_MAIN("\r\n");
break;
case MSGTYPE_I2C_DATA:
DBG_PRINT_MAIN("Main: I2C Data Recieved: ");
for (i = 0; i < length - 1; i++) {
DBG_PRINT_MAIN("%X ", msgbuffer[i]);
}
DBG_PRINT_MAIN(" Event Count: %d", msgbuffer[length - 1]);
DBG_PRINT_MAIN("\r\n");
switch (msgbuffer[0]) {
case 0x2:
length = 1;
// Return size of stored data in buffer
if (buffer_data.stored_length > MSGLEN) {
msgbuffer[0] = MSGLEN;
} else {
msgbuffer[0] = buffer_data.stored_length;
}
DBG_PRINT_MAIN("Main: (I2C Return 0x2) Returning %X\r\n", msgbuffer[0]);
MQ_sendmsg_FromMainToHigh(length, MSGTYPE_I2C_REPLY, (void *) msgbuffer);
break;
case 0x4:
// Return data stored in buffer
if (buffer_data.stored_length > MSGLEN) {
length = MSGLEN;
buffer_read(MSGLEN, msgbuffer);
} else {
length = buffer_data.stored_length;
buffer_read(buffer_data.stored_length, msgbuffer);
}
MQ_sendmsg_FromMainToHigh(length, MSGTYPE_I2C_REPLY, (void *) msgbuffer);
break;
case 0x6:
break;
case 0x7:
break;
case 0x8:
break;
case 0x9:
break;
default:
DBG_PRINT_MAIN("Main: (ERROR) Unexpected message type recieved: %d\r\n", msgbuffer[0]);
break;
};
break;
case MSGTYPE_I2C_MASTER_SEND_COMPLETE:
DBG_PRINT_MAIN("Main: I2C Master Send Complete\r\n");
#ifdef _BASE_STATION
if (i2c_state == I2C_WAIT_WRITE_LENGTH_ACK) {
i2c_master_recv(0x5F, 2); // Request 2 bytes
i2c_state = I2C_WAIT_REPLY_LENGTH;
} else if (i2c_state == I2C_WAIT_WRITE_DATA_ACK) {
i2c_master_recv(0x5F, i2c_bytes_to_read+1); // Request # of bytes
i2c_state = I2C_WAIT_REPLY_DATA;
}
#endif
break;
case MSGTYPE_I2C_MASTER_SEND_FAILED:
DBG_PRINT_MAIN("Main: (ERROR) I2C Master Send Failed\r\n");
break;
case MSGTYPE_I2C_MASTER_RECV_COMPLETE:
DBG_PRINT_MAIN("Main: I2C Master Receive Complete\r\n");
DBG_PRINT_MAIN("Main: (I2C Data) ");
for (i = 0; i < length; i++) {
DBG_PRINT_MAIN("%X ", msgbuffer[i]);
}
DBG_PRINT_MAIN("\r\n");
#ifdef _BASE_STATION
if (i2c_state == I2C_WAIT_REPLY_LENGTH) {
if (msgbuffer[1] == 0xFF) {
i2c_master_recv(0x5F, 2); // Request again
} else if (msgbuffer[1] != 0) {
i2c_bytes_to_read = msgbuffer[1];
// Write [4,#]
msgbuffer[0] = 4;
i2c_master_send(0x5F, 2, msgbuffer);
i2c_state = I2C_WAIT_WRITE_DATA_ACK;
} else {
i2c_state = I2C_STATE_IDLE;
}
} else if (i2c_state == I2C_WAIT_REPLY_DATA) {
if (msgbuffer[1] == 0xFF) {
i2c_master_recv(0x5F, i2c_bytes_to_read+1); // Request again
} else {
for (i = 1; i < length; i++) {
led_driver_num(msgbuffer[i]);
Delay10KTCYx(50);
}
i2c_state = I2C_STATE_IDLE;
}
}
#endif
break;
case MSGTYPE_I2C_MASTER_RECV_FAILED:
DBG_PRINT_MAIN("Main: (ERROR) I2C Master Receive Failed\r\n");
break;
/* -----------------------------------------------------------*/
/* --- XBee Message Handlers ---------------------------------*/
case MSGTYPE_XBEE_RX_AT_COMMAND_RESPONSE:
DBG_PRINT_MAIN("Main: XBee AT command frame\r\n");
frame_at_cmd_response = (void *) msgbuffer;
DBG_PRINT_MAIN("Command: %c%c\r\n", frame_at_cmd_response->command[0], frame_at_cmd_response->command[0]);
DBG_PRINT_MAIN("Status: %d\r\n", frame_at_cmd_response->command_status);
DBG_PRINT_MAIN("Data: ");
for (i = 0; i < length - XBEE_RX_AT_COMMAND_RESPONSE_FRAME_SIZE; i++) {
DBG_PRINT_MAIN("%X ", frame_data_packet->data[i]);
}
DBG_PRINT_MAIN("\r\n");
break;
case MSGTYPE_XBEE_RX_DATA_PACKET:
DBG_PRINT_MAIN("Main: XBee data packet frame\r\n");
frame_data_packet = (void *) msgbuffer;
DBG_PRINT_MAIN("Data: ");
for (i = 0; i < length - XBEE_RX_DATA_PACKET_FRAME_SIZE; i++) {
DBG_PRINT_MAIN("%X ", frame_data_packet->data[i]);
}
DBG_PRINT_MAIN("\r\n");
// Store received data into buffer
buffer_insert(length - XBEE_RX_DATA_PACKET_FRAME_SIZE, frame_data_packet->data);
// Send value of first byte received to LED display
led_driver_num(frame_data_packet->data[0]);
break;
case MSGTYPE_XBEE_RX_DATA_TX_STATUS:
DBG_PRINT_MAIN("Main: XBee TX status frame\r\n");
frame_tx_status = (void *) msgbuffer;
DBG_PRINT_MAIN("Destination: %X\r\n", frame_tx_status->destination_16);
DBG_PRINT_MAIN("Transmit Retry Count: %X\r\n", frame_tx_status->transmit_retry_count);
DBG_PRINT_MAIN("Delivery Status: %X\r\n", frame_tx_status->delivery_status);
DBG_PRINT_MAIN("Discovery Status: %X\r\n", frame_tx_status->discovery_status);
break;
case MSGTYPE_XBEE_RX_IO_DATA_SAMPLE:
DBG_PRINT_MAIN("Main: XBee IO data sample frame\r\n");
frame_io_sample = (void *) msgbuffer;
break;
case MSGTYPE_XBEE_RX_EXPLICIT_COMMAND:
DBG_PRINT_MAIN("Main: XBee explicit command frame\r\n");
frame_explicit_cmd = (void *) msgbuffer;
break;
case MSGTYPE_XBEE_RX_REMOTE_AT_COMMAND_RESPONSE:
DBG_PRINT_MAIN("Main: XBee remote AT command response frame\r\n");
frame_remote_at_cmd = (void *) msgbuffer;
break;
case MSGTYPE_XBEE_RX_ROUTE_RECORD:
DBG_PRINT_MAIN("Main: XBee route record frame\r\n");
frame_route_record = (void *) msgbuffer;
break;
case MSGTYPE_XBEE_RX_NODE_IDENTIFICATION:
DBG_PRINT_MAIN("Main: XBee node identification frame\r\n");
frame_node_identification = (void *) msgbuffer;
break;
case MSGTYPE_XBEE_RX_FRAME_MODEM_STATUS:
DBG_PRINT_MAIN("Main: XBee modem status frame\r\n");
frame_modem_status = (void *) msgbuffer;
DBG_PRINT_MAIN("Status: %X (", frame_modem_status->status);
switch(frame_modem_status->status) {
case 0:
DBG_PRINT_MAIN("Hardware Reset");
break;
case 1:
DBG_PRINT_MAIN("Watchdog Timer Reset");
break;
case 2:
DBG_PRINT_MAIN("Joined Network");
break;
case 3:
DBG_PRINT_MAIN("Disassociated");
break;
case 6:
DBG_PRINT_MAIN("Coordinator Started");
break;
case 7:
DBG_PRINT_MAIN("Network Security Key Updated");
break;
case 0x11:
DBG_PRINT_MAIN("Modem Config Changed While Joining");
break;
}
DBG_PRINT_MAIN(")\r\n");
break;
/* -----------------------------------------------------------*/
};
continue;
}
// Process low priority queue
length = MQ_recvmsg_ToMainFromLow(MSGLEN, &msgtype, (void *) msgbuffer);
if (length < 0) {
// No message, check the error code to see if it is concern
if (length != MSG_QUEUE_EMPTY) {
DBG_PRINT_MAIN("Main: (ERROR) Bad low priority receive, code = %d\r\n", length);
}
} else {
switch (msgtype) {
/* --- Port B Interrupt Handlers -----------------------------*/
case MSGTYPE_PORTB_4_DOWN:
DBG_PRINT_MAIN("Main: Port B4 Down\r\n");
#ifdef _REMOTE
timer3_enable();
#endif
#ifdef _BASE_STATION
// timer0_enable();
#endif
break;
case MSGTYPE_PORTB_4_UP:
DBG_PRINT_MAIN("Main: Port B4 Up\r\n");
#ifdef _REMOTE
timer3_disable();
#endif
#ifdef _BASE_STATION
// timer0_disable();
#endif
break;
case MSGTYPE_PORTB_5_DOWN:
DBG_PRINT_MAIN("Main: Port B5 Down\r\n");
#ifdef _BASE_STATION
// if (i2c_state == I2C_STATE_IDLE) {
// DBG_PRINT_MAIN("Main: Starting I2C Request\r\n");
// /* I2C Demo */
// // Write 2 bytes
// msgbuffer[0] = 0x2;
// msgbuffer[1] = 0x2;
// i2c_master_send(0x5F, 2, msgbuffer);
// i2c_state = I2C_WAIT_WRITE_LENGTH_ACK;
// }
#endif
break;
case MSGTYPE_PORTB_5_UP:
DBG_PRINT_MAIN("Main: Port B5 Up\r\n");
break;
case MSGTYPE_PORTB_6_DOWN:
DBG_PRINT_MAIN("Main: Port B6 Down\r\n");
break;
case MSGTYPE_PORTB_6_UP:
DBG_PRINT_MAIN("Main: Port B6 Up\r\n");
break;
case MSGTYPE_PORTB_7_DOWN:
DBG_PRINT_MAIN("Main: Port B7 Down\r\n");
break;
case MSGTYPE_PORTB_7_UP:
DBG_PRINT_MAIN("Main: Port B7 Up\r\n");
break;
case MSGTYPE_INT1:
// DBG_PRINT_MAIN("Main: INT1 Interrupt\r\n");
break;
/* -----------------------------------------------------------*/
/* --- Timer Interrupt Handlers ------------------------------*/
case MSGTYPE_TIMER0:
DBG_PRINT_MAIN("Main: Timer 0 Interrupt\r\n");
/* XBee Demo */
frame_tx_data = (void *) msgbuffer;
frame_tx_data->frame_type = XBEE_TX_DATA_PACKET;
frame_tx_data->frame_id = 0;
frame_tx_data->destination_64.UPPER_32.long_value = 0x00000000;
frame_tx_data->destination_64.LOWER_32.long_value = 0x00000000;
frame_tx_data->destination_16.INT_16.int_value = 0x0000;
frame_tx_data->broadcast_radius = 0;
frame_tx_data->options = 0x01; // Disable ACK
frame_tx_data->data[0] = counter;
counter++;
if (counter == 100)
counter = 0;
length = XBEE_TX_DATA_PACKET_FRAME_SIZE + 1;
xbee_process_transmit_frame((void *) msgbuffer, length);
Delay10KTCYx(100);
break;
// case MSGTYPE_ADC_NEWVALUE:
// // Get the value in the ADC
// adc_last_value = *((unsigned int*) msgbuffer);
// adc_last_value_shifted = adc_last_value >> 4;
// DBG_PRINT_MAIN("Main: ADC Value = %d\r\n", adc_last_value);
//
// adc_start();
// break;
default:
DBG_PRINT_MAIN("Main: (ERROR) Unexpected msg in low queue, length = %d, type = %d\r\n", length, msgtype);
for (i = 0; i < length; i++) {
DBG_PRINT_MAIN("%X ", msgbuffer[i]);
}
DBG_PRINT_MAIN("\r\n");
break;
};
continue;
}
}
}