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#include "defines.h"
#include "I2C1.h"
static I2C1_DATA *i2c_data_p;
extern uint8_t btn_values[6];
// Set up the data structures for the base_I2C.code
// Should be called once before any i2c routines are called
void I2C1_Init(I2C1_DATA *data) {
i2c_data_p = data;
i2c_data_p->buffer_in_len = 0;
i2c_data_p->buffer_in_len_tmp = 0;
i2c_data_p->buffer_in_read_ind = 0;
i2c_data_p->buffer_in_write_ind = 0;
i2c_data_p->buffer_out_ind = 0;
i2c_data_p->buffer_out_len = 0;
i2c_data_p->operating_mode = 0;
i2c_data_p->operating_state = I2C_IDLE;
i2c_data_p->return_status = 0;
i2c_data_p->slave_in_last_byte = 0;
i2c_data_p->slave_sending_data = 0;
i2c_data_p->master_dest_addr = 0;
i2c_data_p->master_status = I2C_MASTER_IDLE;
// Enable I2C interrupt
PIE1bits.SSP1IE = 1;
}
// Setup the PIC to operate as a master.
void I2C1_Configure_Master(uint8_t speed) {
i2c_data_p->operating_mode = I2C_MODE_MASTER;
I2C_1_CLK_TRIS = 1;
I2C_1_DAT_TRIS = 1;
SSP1STAT = 0x0;
SSP1CON1 = 0x0;
SSP1CON2 = 0x0;
SSP1CON3 = 0x0;
SSP1CON1bits.SSPM = 0x8; // I2C Master Mode
if (speed == 0x01) {
SSP1ADD = 0x13; // Operate at 400KHz (32MHz)
SSP1STATbits.SMP = 1; // Disable Slew Rate Control
} else if (speed == 0x02) {
SSP1ADD = 0x07; // Operate at 1Mhz (32Mhz)
SSP1STATbits.SMP = 1; // Disable Slew Rate Control
} else {
SSP1ADD = 0x4F; // Operate at 100KHz (32MHz)
SSP1STATbits.SMP = 0; // Enable Slew Rate Control
}
SSP1CON1bits.SSPEN = 1; // Enable MSSP1 Module
}
// Sends length number of bytes in msg to specified address (no R/W bit)
void I2C1_Master_Send(uint8_t address, uint8_t length, uint8_t *msg) {
uint8_t i;
if (length == 0)
return;
// Copy message to send into buffer and save length/address
for (i = 0; i < length; i++) {
i2c_data_p->buffer_in[i] = msg[i];
}
i2c_data_p->buffer_in_len = length;
i2c_data_p->master_dest_addr = address;
i2c_data_p->buffer_in_read_ind = 0;
i2c_data_p->buffer_in_write_ind = 0;
// Change status to 'next' operation
i2c_data_p->operating_state = I2C_SEND_ADDR;
i2c_data_p->master_status = I2C_MASTER_SEND;
// Generate start condition
SSP1CON2bits.SEN = 1;
}
// Reads length number of bytes from address (no R/W bit)
void I2C1_Master_Recv(uint8_t address, uint8_t length) {
if (length == 0)
return;
// Save length and address to get data from
i2c_data_p->buffer_in_len = length;
i2c_data_p->master_dest_addr = address;
i2c_data_p->buffer_in_read_ind = 0;
i2c_data_p->buffer_in_write_ind = 0;
// Change status to 'next' operation
i2c_data_p->operating_state = I2C_SEND_ADDR;
i2c_data_p->master_status = I2C_MASTER_RECV;
// Generate start condition
SSP1CON2bits.SEN = 1;
}
// Writes msg to address then reads length number of bytes from address
void I2C1_Master_Restart(uint8_t address, uint8_t msg, uint8_t length) {
uint8_t c;
if (length == 0) {
c = msg;
I2C1_Master_Send(address, 1, &c);
return;
}
// Save length and address to get data from
i2c_data_p->buffer_in[0] = msg;
i2c_data_p->buffer_in_len = length;
i2c_data_p->master_dest_addr = address;
i2c_data_p->buffer_in_read_ind = 0;
i2c_data_p->buffer_in_write_ind = 0;
// Change status to 'next' operation
i2c_data_p->operating_state = I2C_SEND_ADDR;
i2c_data_p->master_status = I2C_MASTER_RESTART;
// Generate start condition
SSP1CON2bits.SEN = 1;
}
// Setup the PIC to operate as a slave. The address must not include the R/W bit
void I2C1_Configure_Slave(uint8_t addr) {
i2c_data_p->operating_mode = I2C_MODE_SLAVE;
// Ensure the two lines are set for input (we are a slave)
I2C_1_CLK_TRIS = 1;
I2C_1_DAT_TRIS = 1;
SSP1ADD = addr << 1; // Set the slave address
SSP1STAT = 0x0;
SSP1CON1 = 0x0;
SSP1CON2 = 0x0;
SSP1CON3 = 0x0;
SSP1CON1bits.SSPM = 0x6; // Enable Slave 7-bit address
SSP1STATbits.SMP = 1; // Slew Off
SSP1CON2bits.SEN = 1; // Enable clock-stretching
SSP1CON3bits.PCIE = 1; // Interrupt on stop condition
SSP1CON3bits.SCIE = 0; // Disable interrupt on start condition
SSP1CON1bits.SSPEN = 1; // Enable MSSP1 Module
}
void I2C1_Interrupt_Handler() {
// Call interrupt depending on which mode we are operating in
if (i2c_data_p->operating_mode == I2C_MODE_MASTER) {
I2C1_Interrupt_Master();
} else if (i2c_data_p->operating_mode == I2C_MODE_SLAVE) {
I2C1_Interrupt_Slave();
}
}
// An internal subroutine used in the master version of the i2c_interrupt_handler
void I2C1_Interrupt_Master() {
// If we are in the middle of sending data
if (i2c_data_p->master_status == I2C_MASTER_SEND) {
switch (i2c_data_p->operating_state) {
case I2C_IDLE:
break;
case I2C_SEND_ADDR:
// Send the address with read bit set
i2c_data_p->operating_state = I2C_CHECK_ACK_SEND;
SSP1BUF = (i2c_data_p->master_dest_addr << 1) | 0x0;
break;
case I2C_CHECK_ACK_SEND:
// Check if ACK is received or not
if (!SSP1CON2bits.ACKSTAT) {
// If an ACK is received, send next byte of data
if (i2c_data_p->buffer_in_read_ind < i2c_data_p->buffer_in_len) {
SSP1BUF = i2c_data_p->buffer_in[i2c_data_p->buffer_in_read_ind];
i2c_data_p->buffer_in_read_ind++;
} else {
// If no more data is to be sent, send stop bit
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_SEND_OK;
}
} else {
// If a NACK is received, stop transmission and send error
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_SEND_FAIL;
}
break;
}
// If we are in the middle of receiving data
} else if (i2c_data_p->master_status == I2C_MASTER_RECV) {
switch (i2c_data_p->operating_state) {
case I2C_IDLE:
break;
case I2C_SEND_ADDR:
// Send address with write bit set
i2c_data_p->operating_state = I2C_CHECK_ACK_RECV;
uint8_t tmp = (i2c_data_p->master_dest_addr << 1);
tmp |= 0x01;
SSP1BUF = tmp;
break;
case I2C_CHECK_ACK_RECV:
// Check if ACK is received
if (!SSP1CON2bits.ACKSTAT) {
// If an ACK is received, set module to receive 1 byte of data
i2c_data_p->operating_state = I2C_RCV_DATA;
SSP1CON2bits.RCEN = 1;
} else {
// If a NACK is received, stop transmission and send error
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_RECV_FAIL;
}
break;
case I2C_RCV_DATA:
// On receive, save byte into buffer
// TODO: Handle I2C buffer overflow
i2c_data_p->buffer_in[i2c_data_p->buffer_in_write_ind] = SSP1BUF;
i2c_data_p->buffer_in_write_ind++;
if (i2c_data_p->buffer_in_write_ind < i2c_data_p->buffer_in_len) {
// If we still need to read, send an ACK to the slave
i2c_data_p->operating_state = I2C_REQ_DATA;
SSP1CON2bits.ACKDT = 0; // ACK
SSP1CON2bits.ACKEN = 1;
} else {
// If we are done reading, send an NACK to the slave
i2c_data_p->operating_state = I2C_SEND_STOP;
SSP1CON2bits.ACKDT = 1; // NACK
SSP1CON2bits.ACKEN = 1;
}
break;
case I2C_REQ_DATA:
// Set module to receive one byte of data
i2c_data_p->operating_state = I2C_RCV_DATA;
SSP1CON2bits.RCEN = 1;
break;
case I2C_SEND_STOP:
// Send the stop bit and copy message to send to Main()
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_RECV_OK;
break;
}
} else if (i2c_data_p->master_status == I2C_MASTER_RESTART) {
switch (i2c_data_p->operating_state) {
case I2C_IDLE:
break;
case I2C_SEND_ADDR:
// Send the address with read bit set
i2c_data_p->operating_state = I2C_CHECK_ACK_SEND;
SSP1BUF = (i2c_data_p->master_dest_addr << 1) | 0x0;
break;
case I2C_CHECK_ACK_SEND:
// Check if ACK is received or not
if (!SSP1CON2bits.ACKSTAT) {
// If an ACK is received, send first byte of data
SSP1BUF = i2c_data_p->buffer_in[0];
i2c_data_p->operating_state = I2C_CHECK_ACK_RESTART;
} else {
// If a NACK is received, stop transmission and send error
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_SEND_FAIL;
}
break;
case I2C_CHECK_ACK_RESTART:
if (!SSP1CON2bits.ACKSTAT) {
SSP1CON2bits.RSEN = 1;
i2c_data_p->operating_state = I2C_SEND_ADDR_2;
} else {
// If a NACK is received, stop transmission and send error
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_SEND_FAIL;
}
break;
case I2C_SEND_ADDR_2:
// Send the address with read bit set
i2c_data_p->operating_state = I2C_CHECK_ACK_RECV;
uint8_t tmp = (i2c_data_p->master_dest_addr << 1);
tmp |= 0x01;
SSP1BUF = tmp;
break;
case I2C_CHECK_ACK_RECV:
// Check if ACK is received
if (!SSP1CON2bits.ACKSTAT) {
// If an ACK is received, set module to receive 1 byte of data
i2c_data_p->operating_state = I2C_RCV_DATA;
SSP1CON2bits.RCEN = 1;
} else {
// If a NACK is received, stop transmission and send error
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_RECV_FAIL;
}
break;
case I2C_RCV_DATA:
// On receive, save byte into buffer
// TODO: Handle I2C buffer overflow
i2c_data_p->buffer_in[i2c_data_p->buffer_in_write_ind] = SSP1BUF;
i2c_data_p->buffer_in_write_ind++;
if (i2c_data_p->buffer_in_write_ind < i2c_data_p->buffer_in_len) {
// If we still need to read, send an ACK to the slave
i2c_data_p->operating_state = I2C_REQ_DATA;
SSP1CON2bits.ACKDT = 0; // ACK
SSP1CON2bits.ACKEN = 1;
} else {
// If we are done reading, send an NACK to the slave
i2c_data_p->operating_state = I2C_SEND_STOP;
SSP1CON2bits.ACKDT = 1; // NACK
SSP1CON2bits.ACKEN = 1;
}
break;
case I2C_REQ_DATA:
// Set module to receive one byte of data
i2c_data_p->operating_state = I2C_RCV_DATA;
SSP1CON2bits.RCEN = 1;
break;
case I2C_SEND_STOP:
// Send the stop bit
i2c_data_p->operating_state = I2C_IDLE;
SSP1CON2bits.PEN = 1;
i2c_data_p->master_status = I2C_MASTER_IDLE;
i2c_data_p->return_status = I2C_RECV_OK;
break;
}
}
}
void I2C1_Interrupt_Slave() {
uint8_t received_data;
uint8_t data_read_from_buffer = 0;
uint8_t data_written_to_buffer = 0;
uint8_t overrun_error = 0;
// Clear SSPOV (overflow bit)
if (SSP1CON1bits.SSPOV == 1) {
SSP1CON1bits.SSPOV = 0;
// We failed to read the buffer in time, so we know we
// can't properly receive this message, just put us in the
// a state where we are looking for a new message
i2c_data_p->operating_state = I2C_IDLE;
overrun_error = 1;
i2c_data_p->return_status = I2C_ERR_OVERRUN;
}
// Read SPPxBUF if it is full
if (SSP1STATbits.BF == 1) {
received_data = SSP1BUF;
data_read_from_buffer = 1;
}
if (!overrun_error) {
switch (i2c_data_p->operating_state) {
case I2C_IDLE:
{
// // Ignore anything except a start
// if (SSP1STATbits.S == 1) {
// i2c_data_p->buffer_in_len_tmp = 0;
// i2c_data_p->operating_state = I2C_STARTED;
// }
// break;
// }
// case I2C_STARTED:
// {
// In this case, we expect either an address or a stop bit
if (SSP1STATbits.P == 1) {
// Return to idle mode
i2c_data_p->operating_state = I2C_IDLE;
} else if (data_read_from_buffer) {
i2c_data_p->buffer_in_len_tmp = 0;
if (SSP1STATbits.D_nA == 0) {
// Address received
if (SSP1STATbits.R_nW == 0) {
// Slave write mode
i2c_data_p->operating_state = I2C_RCV_DATA;
} else {
// Slave read mode
i2c_data_p->operating_state = I2C_SEND_DATA;
// Process the first byte immediatly if sending data
goto send;
}
} else {
i2c_data_p->operating_state = I2C_IDLE;
i2c_data_p->return_status = I2C_ERR_NOADDR;
}
}
break;
}
send:
case I2C_SEND_DATA:
{
if (!i2c_data_p->slave_sending_data) {
// If we are not currently sending data, figure out what to reply with
if (I2C1_Process_Receive(i2c_data_p->slave_in_last_byte)) {
// Data exists to be returned, send first byte
SSP1BUF = i2c_data_p->buffer_out[0];
i2c_data_p->buffer_out_ind = 1;
i2c_data_p->slave_sending_data = 1;
data_written_to_buffer = 1;
} else {
// Unknown request
i2c_data_p->slave_sending_data = 0;
i2c_data_p->operating_state = I2C_IDLE;
}
} else {
// Sending remaining data back to master
if (i2c_data_p->buffer_out_ind < i2c_data_p->buffer_out_len) {
SSP1BUF = i2c_data_p->buffer_out[i2c_data_p->buffer_out_ind];
i2c_data_p->buffer_out_ind++;
data_written_to_buffer = 1;
} else {
// Nothing left to send
i2c_data_p->slave_sending_data = 0;
i2c_data_p->operating_state = I2C_IDLE;
}
}
break;
}
case I2C_RCV_DATA:
{
// We expect either data or a stop bit or a (if a restart, an addr)
if (SSP1STATbits.P == 1) {
// Stop bit detected, we need to check to see if we also read data
if (data_read_from_buffer) {
if (SSP1STATbits.D_nA == 1) {
// Data received with stop bit
// TODO: Handle I2C buffer overflow
i2c_data_p->buffer_in[i2c_data_p->buffer_in_write_ind] = received_data;
if (i2c_data_p->buffer_in_write_ind == MAXI2C1BUF-1) {
i2c_data_p->buffer_in_write_ind = 0;
} else {
i2c_data_p->buffer_in_write_ind++;
}
i2c_data_p->buffer_in_len_tmp++;
// Save the last byte received
i2c_data_p->slave_in_last_byte = received_data;
i2c_data_p->return_status = I2C_DATA_AVAL;
} else {
i2c_data_p->operating_state = I2C_IDLE;
i2c_data_p->return_status = I2C_ERR_NODATA;
}
}
i2c_data_p->buffer_in_len += i2c_data_p->buffer_in_len_tmp;
i2c_data_p->operating_state = I2C_IDLE;
} else if (data_read_from_buffer) {
if (SSP1STATbits.D_nA == 1) {
// Data received
i2c_data_p->buffer_in[i2c_data_p->buffer_in_write_ind] = received_data;
if (i2c_data_p->buffer_in_write_ind == MAXI2C1BUF-1) {
i2c_data_p->buffer_in_write_ind = 0;
} else {
i2c_data_p->buffer_in_write_ind++;
}
i2c_data_p->buffer_in_len_tmp++;
// Save the last byte received
i2c_data_p->slave_in_last_byte = received_data;
i2c_data_p->return_status = I2C_DATA_AVAL;
} else {
// Restart bit detected
if (SSP1STATbits.R_nW == 1) {
i2c_data_p->buffer_in_len += i2c_data_p->buffer_in_len_tmp;
i2c_data_p->operating_state = I2C_SEND_DATA;
// Process the first byte immediatly if sending data
goto send;
} else {
// Bad to recv an address again, we aren't ready
i2c_data_p->operating_state = I2C_IDLE;
i2c_data_p->return_status = I2C_ERR_NODATA;
}
}
}
break;
}
}
}
// Release the clock stretching bit (if we should)
if (data_read_from_buffer || data_written_to_buffer) {
// Release the clock
if (SSP1CON1bits.CKP == 0) {
SSP1CON1bits.CKP = 1;
}
}
}
/* Returns 0 if I2C module is currently busy, otherwise returns status code */
uint8_t I2C1_Get_Status() {
if (i2c_data_p->operating_mode == I2C_MODE_MASTER) {
if (i2c_data_p->master_status != I2C_MASTER_IDLE || i2c_data_p->buffer_in_len == 0) {
return 0;
} else {
return i2c_data_p->return_status;
}
} else {
if (i2c_data_p->operating_state != I2C_IDLE || i2c_data_p->buffer_in_len == 0) {
return 0;
} else {
return i2c_data_p->return_status;
}
}
}
uint8_t I2C1_Buffer_Len() {
return i2c_data_p->buffer_in_len;
}
/* Returns 0 if I2C module is currently busy, otherwise returns buffer length */
uint8_t I2C1_Read_Buffer(uint8_t *buffer) {
uint8_t i = 0;
while (i2c_data_p->buffer_in_len != 0) {
buffer[i] = i2c_data_p->buffer_in[i2c_data_p->buffer_in_read_ind];
i++;
if (i2c_data_p->buffer_in_read_ind == MAXI2C1BUF-1) {
i2c_data_p->buffer_in_read_ind = 0;
} else {
i2c_data_p->buffer_in_read_ind++;
}
i2c_data_p->buffer_in_len--;
}
return i;
}
/* Put data to be returned here */
uint8_t I2C1_Process_Receive(uint8_t c) {
uint8_t ret = 0;
switch (c) {
case CMD_QUERY_BTN:
i2c_data_p->buffer_out[0] = btn_values[0];
i2c_data_p->buffer_out[1] = btn_values[1];
i2c_data_p->buffer_out[2] = btn_values[2];
i2c_data_p->buffer_out[3] = btn_values[3];
i2c_data_p->buffer_out[4] = btn_values[4];
i2c_data_p->buffer_out[5] = btn_values[5];
i2c_data_p->buffer_out_len = 6;
ret = 1;
break;
default:
break;
}
return ret;
}