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ecanFunctions.c
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ecanFunctions.c
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#include "ecanFunctions.h"
#include "CircularBuffer.h"
#include <string.h>
#include <stdbool.h>
/**
* @file ecanFunctions.c
* @author Bryant Mairs
* @author Pavlo Manovi
* @date September 28th, 202
* @brief Provides C functions for ECAN blocks
*/
// Specify the number of 8-byte CAN messages buffer supports.
// This can be overridden by user code.
#ifndef ECAN1_BUFFERSIZE
#define ECAN1_BUFFERSIZE 8 * 24
#endif
// Declare space for our message buffer in DMA
uint16_t ecan1msgBuf[4][8] __attribute__((space(dma)));
// Initialize our circular buffers and data arrays for transreceiving CAN messages
CircularBuffer ecan1_rx_buffer;
uint8_t rx_data_array[ECAN1_BUFFERSIZE];
CircularBuffer ecan1_tx_buffer;
uint8_t tx_data_array[ECAN1_BUFFERSIZE];
// Track whether or not we're currently transmitting
unsigned char currentlyTransmitting = 0;
unsigned char receivedMessagesPending = 0;
void ecan1_init(const uint16_t *parameters)
{
// Make sure the ECAN module is in configuration mode.
// It should be this way after a hardware reset, but
// we make sure anyways.
C1CTRL1bits.REQOP = 4;
while (C1CTRL1bits.OPMODE != 4);
// Initialize our circular buffers. If this fails, we crash and burn.
if (!CB_Init(&ecan1_tx_buffer, tx_data_array, ECAN1_BUFFERSIZE)) {
while (1);
}
if (!CB_Init(&ecan1_rx_buffer, rx_data_array, ECAN1_BUFFERSIZE)) {
while (1);
}
// Initialize our time quanta
uint16_t a = parameters[3] & 0x0007;
uint16_t b = (parameters[3] & 0x0038) >> 3;
uint16_t c = (parameters[3] & 0x01C0) >> 6;
uint32_t ftq = parameters[2] / parameters[1]*10;
ftq = ftq / (2 * (a + b + c + 4)); // Divide by the 2*number of time quanta (4 is because of the 1-offset for a/b/c and the sync segment)
C1CFG1bits.BRP = ftq - 1;
C1CFG1bits.SJW = (parameters[3] & 0x0600) >> 9;
C1CFG2bits.SEG1PH = a; // Set segment 1 time
C1CFG2bits.PRSEG = b; // Set propagation segment time
C1CFG2bits.SEG2PHTS = 0x1; // Keep segment 2 time programmable
C1CFG2bits.SEG2PH = c; // Set phase segment 2 time
C1CFG2bits.SAM = (parameters[3] & 0x0800) >> 11; // Triple-sample for majority rules at bit sample point
// Setup our frequencies for time quanta calculations.
// FCAN is selected to be FCY: FCAN = FCY = 40MHz. This is actually a don't care bit in dsPIC33f
C1CTRL1bits.CANCKS = 1;
C1FCTRLbits.DMABS = 0; // Use 4 buffers in DMA RAM
// Setup message filters and masks.
C1CTRL1bits.WIN = 1; // Allow configuration of masks and filters
// Set our filter mask parameters
C1RXM0SIDbits.SID = parameters[7] >> 5; // Set filter 0
C1RXM0SIDbits.MIDE = (parameters[7] & 0x0008) >> 3;
C1RXM0EID = parameters[8];
C1RXM1SIDbits.SID = parameters[9] >> 5; // Set filter 1
C1RXM1SIDbits.MIDE = (parameters[9] & 0x0008) >> 3;
C1RXM1EID = parameters[10];
C1RXM2SIDbits.SID = parameters[11] >> 5; // Set filter 2
C1RXM2SIDbits.MIDE = (parameters[11] & 0x0008) >> 3;
C1RXM2EID = parameters[12];
C1FEN1 = parameters[4]; // Enable desired filters
C1FMSKSEL1 = parameters[5]; // Set filter mask selection bits for filters 0-7
C1FMSKSEL2 = parameters[6]; // Set filter mask selection bits for filters 8-15
C1BUFPNT1 = parameters[17]; // Buffer pointer for filters 0-3
C1BUFPNT2 = parameters[18]; // Buffer pointer for filters 4-7
C1BUFPNT3 = parameters[19]; // Buffer pointer for filters 8-11
C1BUFPNT4 = parameters[20]; // Buffer pointer for filters 12-15x
// Set our filter parameters
C1RXF0SID = parameters[21];
C1RXF0EID = parameters[22];
C1RXF1SID = parameters[23];
C1RXF1EID = parameters[24];
C1RXF2SID = parameters[25];
C1RXF2EID = parameters[26];
C1RXF3SID = parameters[27];
C1RXF3EID = parameters[28];
C1RXF4SID = parameters[29];
C1RXF4EID = parameters[30];
C1RXF5SID = parameters[31];
C1RXF5EID = parameters[32];
C1RXF6SID = parameters[33];
C1RXF6EID = parameters[34];
C1RXF7SID = parameters[35];
C1RXF7EID = parameters[36];
C1RXF8SID = parameters[37];
C1RXF8EID = parameters[38];
C1RXF9SID = parameters[39];
C1RXF9EID = parameters[40];
C1RXF10SID = parameters[41];
C1RXF10EID = parameters[42];
C1RXF11SID = parameters[43];
C1RXF11EID = parameters[44];
C1RXF12SID = parameters[45];
C1RXF12EID = parameters[46];
C1RXF13SID = parameters[47];
C1RXF13EID = parameters[48];
C1RXF14SID = parameters[49];
C1RXF14EID = parameters[50];
C1RXF15SID = parameters[51];
C1RXF15EID = parameters[52];
C1CTRL1bits.WIN = 0;
// Return the modules to specified operating mode.
// 0 normal, 1 disable, 2 loopback, 3 listen-only, 4 configuration, 7 listen all messages
uint8_t desired_mode = (parameters[0] & 0x001C) >> 2;
C1CTRL1bits.REQOP = desired_mode;
while (C1CTRL1bits.OPMODE != desired_mode);
// Clear all interrupt bits
C1RXFUL1 = C1RXFUL2 = C1RXOVF1 = C1RXOVF2 = 0x0000;
// Enable interrupts for ECAN1
IEC2bits.C1IE = 1; // Enable interrupts for ECAN1 peripheral
C1INTEbits.TBIE = 1; // Enable TX buffer interrupt
C1INTEbits.RBIE = 1; // Enable RX buffer interrupt
// Configure buffer settings.
// Must be done after mode setting for some reason
// (can't find documentation on it)
C1TR01CON = parameters[13];
C1TR23CON = parameters[14];
C1TR45CON = parameters[15];
C1TR67CON = parameters[16];
// Setup necessary DMA channels for transmission and reception
// Transmission DMA
uint16_t dmaParameters[6];
dmaParameters[0] = 0x4648;
dmaParameters[1] = (uint16_t) & C1TXD;
dmaParameters[2] = 7;
dmaParameters[3] = __builtin_dmaoffset(ecan1msgBuf);
dmaParameters[4] = ((parameters[0] >> 5) & 7);
dmaParameters[5] = 0;
dma_init(dmaParameters);
// Reception DMA
dmaParameters[0] = 0x2208;
dmaParameters[1] = (uint16_t) & C1RXD;
dmaParameters[4] = ((parameters[0] >> 8) & 7);
dma_init(dmaParameters);
}
int ecan1_receive(tCanMessage *msg, uint8_t *messagesLeft)
{
int foundOne = CB_ReadMany(&ecan1_rx_buffer, msg, sizeof(tCanMessage));
if (messagesLeft) {
if (foundOne) {
*messagesLeft = --receivedMessagesPending;
} else {
*messagesLeft = 0;
}
}
return foundOne;
}
int ecan1_receive_matlab(uint32_t *output)
{
tCanMessage msg;
if (receivedMessagesPending > 0) {
CB_ReadMany(&ecan1_rx_buffer, &msg, sizeof(tCanMessage));
output[0] = msg.id;
output[1] = ((uint32_t) msg.payload[3]) << 24;
output[1] |= ((uint32_t) msg.payload[2]) << 16;
output[1] |= ((uint32_t) msg.payload[1]) << 8;
output[1] |= (uint32_t) msg.payload[0];
output[2] = ((uint32_t) msg.payload[7]) << 24;
output[2] |= ((uint32_t) msg.payload[6]) << 16;
output[2] |= ((uint32_t) msg.payload[5]) << 8;
output[2] |= (uint32_t) msg.payload[4];
output[3] = (uint32_t) msg.validBytes;
if (msg.message_type == CAN_MSG_RTR) {
output[3] |= 0x00000100;
}
output[3] |= ((uint32_t) receivedMessagesPending--) << 16;
return true;
} else {
int i;
for(i = 0; i < 4; i++) {
output[i] = 0;
}
return false;
}
}
// NOTE: We do not block for message transmission to complete. Message queuing
// is handled by the transmission circular buffer.
void ecan1_transmit(const tCanMessage *message)
{
uint32_t word0 = 0, word1 = 0, word2 = 0;
uint32_t sid10_0 = 0, eid5_0 = 0, eid17_6 = 0;
uint16_t *ecan_msg_buf_ptr = ecan1msgBuf[message->buffer];
// Variables for setting correct TXREQ bit
uint16_t bit_to_set;
uint16_t offset;
uint16_t *bufferCtrlRegAddr;
// Divide the identifier into bit-chunks for storage
// into the registers.
if (message->frame_type == CAN_FRAME_EXT) {
eid5_0 = (message->id & 0x3F);
eid17_6 = (message->id >> 6) & 0xFFF;
sid10_0 = (message->id >> 18) & 0x7FF;
word0 = 1;
word1 = eid17_6;
} else {
sid10_0 = (message->id & 0x7FF);
}
word0 |= (sid10_0 << 2);
word2 |= (eid5_0 << 10);
// Set remote transmit bits
if (message->message_type == CAN_MSG_RTR) {
word0 |= 0x2;
word2 |= 0x0200;
}
ecan_msg_buf_ptr[0] = word0;
ecan_msg_buf_ptr[1] = word1;
ecan_msg_buf_ptr[2] = ((word2 & 0xFFF0) + message->validBytes);
ecan_msg_buf_ptr[3] = ((uint16_t) message->payload[1] << 8 | ((uint16_t) message->payload[0]));
ecan_msg_buf_ptr[4] = ((uint16_t) message->payload[3] << 8 | ((uint16_t) message->payload[2]));
ecan_msg_buf_ptr[5] = ((uint16_t) message->payload[5] << 8 | ((uint16_t) message->payload[4]));
ecan_msg_buf_ptr[6] = ((uint16_t) message->payload[7] << 8 | ((uint16_t) message->payload[6]));
// Set the correct transfer intialization bit (TXREQ) based on message buffer.
offset = message->buffer >> 1;
bufferCtrlRegAddr = (uint16_t *) (&C1TR01CON + offset);
bit_to_set = 1 << (3 | ((message->buffer & 1) << 3));
*bufferCtrlRegAddr |= bit_to_set;
// Keep track of whether we're in a transmission train or not.
currentlyTransmitting = 1;
}
/**
* Transmits a tCanMessage using the transmission circular buffer.
*/
void ecan1_buffered_transmit(const tCanMessage *msg)
{
// Append the message to the queue.
// Message are only removed upon successful transmission.
// They will be overwritten by newer message overflowing
// the circular buffer however.
CB_WriteMany(&ecan1_tx_buffer, msg, sizeof(tCanMessage), true);
// If this is the only message in the queue, attempt to
// transmit it.
if (!currentlyTransmitting) {
ecan1_transmit(msg);
}
}
/**
* Merely preprocesses data from the MATLAB array format
* into a tCanMessage to be passed to ecan1_buffered_transmit()
*/
void ecan1_buffered_transmit_matlab(const uint16_t *data)
{
tCanMessage message;
message.id = ((uint32_t) data[1]) | (((uint32_t) data[2]) << 16);
message.buffer = (uint8_t) data[0];
// Set remote transmit bits
if ((data[3] & 0xFF00) == 0) {
message.message_type = CAN_MSG_DATA;
} else {
message.message_type = CAN_MSG_RTR;
}
// Set extended frame bits
if ((data[3] & 0xFF) == 0) {
message.frame_type = CAN_FRAME_STD;
} else {
message.frame_type = CAN_FRAME_EXT;
}
// Set data and data length bits
message.payload[0] = (uint8_t) data[4];
message.payload[1] = (uint8_t) ((data[4] & 0xFF00) >> 8);
message.payload[2] = (uint8_t) data[5];
message.payload[3] = (uint8_t) ((data[5] & 0xFF00) >> 8);
message.payload[4] = (uint8_t) data[6];
message.payload[5] = (uint8_t) ((data[6] & 0xFF00) >> 8);
message.payload[6] = (uint8_t) data[7];
message.payload[7] = (uint8_t) ((data[7] & 0xFF00) >> 8);
message.validBytes = (data[0] & 0xFF00) >> 8;
// Transmit the message via the circular buffer
ecan1_buffered_transmit(&message);
}
void ecan1_error_status_matlab(uint8_t *errors)
{
// Set transmission errors in first array element.
if (C1INTFbits.TXBO) {
errors[0] = 3;
} else if (C1INTFbits.TXBP) {
errors[0] = 2;
} else if (C1INTFbits.TXWAR) {
errors[0] = 1;
}
// Set reception errors in second array element.
if (C1INTFbits.RXBP) {
errors[1] = 2;
} else if (C1INTFbits.RXWAR) {
errors[1] = 1;
}
}
void dma_init(const uint16_t *parameters)
{
// Determine the correct addresses for all needed registers
uint16_t offset = (parameters[4]*6);
uint16_t *chanCtrlRegAddr = (uint16_t *) (&DMA0CON + offset);
uint16_t *irqSelRegAddr = (uint16_t *) (&DMA0REQ + offset);
uint16_t *addrOffsetRegAddr = (uint16_t *) (&DMA0STA + offset);
uint16_t *secAddrOffsetRegAddr = (uint16_t *) (&DMA0STB + offset);
uint16_t *periAddrRegAddr = (uint16_t *) (&DMA0PAD + offset);
uint16_t *transCountRegAddr = (uint16_t *) (&DMA0CNT + offset);
DMACS0 = 0; // Clear the status register
*periAddrRegAddr = (uint16_t) parameters[1]; // Set the peripheral address that will be using DMA
*transCountRegAddr = (uint16_t) parameters[2]; // Set data units to words or bytes
*irqSelRegAddr = (uint16_t) (parameters[0] >> 8); // Set the IRQ priority for the DMA transfer
*addrOffsetRegAddr = (uint16_t) parameters[3]; // Set primary DPSRAM start address bits
*secAddrOffsetRegAddr = (uint16_t) parameters[5]; // Set secondary DPSRAM start address bits
// Setup the configuration register & enable DMA
*chanCtrlRegAddr = (uint16_t) (0x8000 | ((parameters[0] & 0x00F0) << 7) | ((parameters[0] & 0x000C) << 2));
}
/**
* This is an interrupt handler for the ECAN1 peripheral.
* It clears interrupt bits and pushes received message into
* the circular buffer.
*/
void __attribute__((interrupt, no_auto_psv))_C1Interrupt(void)
{
// Give us a CAN message struct to populate and use
tCanMessage message;
uint8_t ide = 0;
uint8_t srr = 0;
uint32_t id = 0;
uint16_t *ecan_msg_buf_ptr;
// If the interrupt was set because of a transmit, check to
// see if more messages are in the circular buffer and start
// transmitting them.
if (C1INTFbits.TBIF) {
// After a successfully sent message, there should be at least
// one message in the queue, so pop it off.
CB_ReadMany(&ecan1_tx_buffer, &message, sizeof(tCanMessage));
// Check for a buffer overflow. Then clear the entire buffer if there was.
if (ecan1_tx_buffer.overflowCount) {
CB_Init(&ecan1_tx_buffer, tx_data_array, ECAN1_BUFFERSIZE);
}
// Now if there's still a message left in the buffer,
// try to transmit it.
if (ecan1_tx_buffer.dataSize >= sizeof(tCanMessage)) {
tCanMessage msg;
CB_PeekMany(&ecan1_tx_buffer, &msg, sizeof(tCanMessage));
ecan1_transmit(&msg);
} else {
currentlyTransmitting = 0;
}
C1INTFbits.TBIF = 0;
}
// If the interrupt was fired because of a received message
// package it all up and store in the circular buffer.
if (C1INTFbits.RBIF) {
// Obtain the buffer the message was stored into, checking that the value is valid to refer to a buffer
if (C1VECbits.ICODE < 32) {
message.buffer = C1VECbits.ICODE;
}
ecan_msg_buf_ptr = ecan1msgBuf[message.buffer];
// Clear the buffer full status bit so more messages can be received.
if (C1RXFUL1 & (1 << message.buffer)) {
C1RXFUL1 &= ~(1 << message.buffer);
}
// Move the message from the DMA buffer to a data structure and then push it into our circular buffer.
// Read the first word to see the message type
ide = ecan_msg_buf_ptr[0] & 0x0001;
srr = ecan_msg_buf_ptr[0] & 0x0002;
/* Format the message properly according to whether it
* uses an extended identifier or not.
*/
if (ide == 0) {
message.frame_type = CAN_FRAME_STD;
message.id = (uint32_t) ((ecan_msg_buf_ptr[0] & 0x1FFC) >> 2);
} else {
message.frame_type = CAN_FRAME_EXT;
id = ecan_msg_buf_ptr[0] & 0x1FFC;
message.id = id << 16;
id = ecan_msg_buf_ptr[1] & 0x0FFF;
message.id |= id << 6;
id = ecan_msg_buf_ptr[2] & 0xFC00;
message.id |= id >> 10;
}
/* If message is a remote transmit request, mark it as such.
* Otherwise it will be a regular transmission so fill its
* payload with the relevant data.
*/
if (srr == 1) {
message.message_type = CAN_MSG_RTR;
} else {
message.message_type = CAN_MSG_DATA;
message.validBytes = (uint8_t) (ecan_msg_buf_ptr[2] & 0x000F);
message.payload[0] = (uint8_t) ecan_msg_buf_ptr[3];
message.payload[1] = (uint8_t) ((ecan_msg_buf_ptr[3] & 0xFF00) >> 8);
message.payload[2] = (uint8_t) ecan_msg_buf_ptr[4];
message.payload[3] = (uint8_t) ((ecan_msg_buf_ptr[4] & 0xFF00) >> 8);
message.payload[4] = (uint8_t) ecan_msg_buf_ptr[5];
message.payload[5] = (uint8_t) ((ecan_msg_buf_ptr[5] & 0xFF00) >> 8);
message.payload[6] = (uint8_t) ecan_msg_buf_ptr[6];
message.payload[7] = (uint8_t) ((ecan_msg_buf_ptr[6] & 0xFF00) >> 8);
}
// Store the message in the buffer
CB_WriteMany(&ecan1_rx_buffer, &message, sizeof(tCanMessage), true);
// Increase the number of messages stored in the buffer
++receivedMessagesPending;
// Be sure to clear the interrupt flag.
C1INTFbits.RBIF = 0;
}
// Clear the general ECAN1 interrupt flag.
IFS2bits.C1IF = 0;
}