kemonine/serial_debugger
kemonine
/
serial_debugger
1
0
Fork 0
Code Issues 1 Pull Requests Projects 3 Releases Activity
serial_debugger/hardware/mux_rpi/mux_rpi.ino

205 lines
6.2 KiB
C++
Raw Permalink Blame History

// References / Resources / Inspiration
// https://gist.github.com/nonsintetic/ad13e70f164801325f5f552f84306d6f
// Varous system includes
#include <Arduino.h>
#include "wiring_private.h"
// Various library includes
#include <CircularBuffer.h>
// Buffer for serial data -> i2c
CircularBuffer<byte, 16 * 1024> uartBufferOutbound;
// Buffer for serial data <- i2c
CircularBuffer<byte, 1024> uartBufferInbound;
// Board LED Pin
#define PIN_BOARD_LED 13
// Blinking timer setup
#define TIMER_MILLIS 500
bool ledState = false;
void TC5_Handler(void);
void timerConfigure(int sampleRate);
// General UART configuration struct
struct {
// Whether or not the USB is used for serial communications (stand alone builds)
bool Serial = true;
// Whether or not the i2c is used for serial communication (_controller builds)
bool uartI2C = false;
// Use the generic uart setup with the rpi
bool Serial1 = true;
// Use uart0 on the rpi
bool rpiUART0 = true;
// Use uart5 on the rpi
bool rpiUART5 = true;
} uartConfig;
// Additional serial ports for communication <> RPI
// https://learn.adafruit.com/using-atsamd21-sercom-to-add-more-spi-i2c-serial-ports?view=all#creating-a-new-serial
// D11 (RX) -- GPIO 8 (TX)
// D10 (TX) -- GPIO 10 (RX)
// MISO (RX) -- GPIO 32 (TX)
// MOSI (TX) -- GPIO 33 (RX)
Uart rpiUART0 (&sercom1, 10, 11, SERCOM_RX_PAD_0, UART_TX_PAD_2);
Uart rpiUART5 (&sercom4, PIN_SPI_MISO, PIN_SPI_MOSI, SERCOM_RX_PAD_0, UART_TX_PAD_2);
void SERCOM1_Handler() {
rpiUART0.IrqHandler();
}
void SERCOM4_Handler() {
rpiUART5.IrqHandler();
}
// Misc uart functions (defined after setup/loop)
void setupUARTs();
// Setup stuff needed for build
void setup() {
// Setup board LED
pinMode(PIN_BOARD_LED, OUTPUT);
// Timer setup
timerConfigure(TIMER_MILLIS);
timerStartCounter();
// Setup UARTS
setupUARTs();
// Assign SERCOM functionality
pinPeripheral(10, PIO_SERCOM);
pinPeripheral(11, PIO_SERCOM);
}
// Main function
int serialIncomingByte;
void loop() {
while (uartConfig.Serial && Serial.available()) {
uartBufferOutbound.push(Serial.read());
if (uartConfig.Serial1) {
Serial1.write(uartBufferOutbound.last());
}
if (uartConfig.rpiUART0) {
rpiUART0.write(uartBufferOutbound.last());
}
if (uartConfig.rpiUART5) {
rpiUART5.write(uartBufferOutbound.last());
}
}
while (uartConfig.Serial1 && Serial1.available()) {
uartBufferInbound.push(Serial1.read());
if (uartConfig.Serial) {
Serial.write(uartBufferInbound.last());
}
}
while (uartConfig.rpiUART0 && rpiUART0.available()) {
uartBufferInbound.push(rpiUART0.read());
if (uartConfig.Serial) {
Serial.write(uartBufferInbound.last());
}
}
while (uartConfig.rpiUART5 && rpiUART5.available()) {
uartBufferInbound.push(rpiUART5.read());
if (uartConfig.Serial) {
Serial.write(uartBufferInbound.last());
}
}
}
// Method to setup / reset the uarts
void setupUARTs() {
// Close ALL serial ports and re-enable per config (config can change during runtime)
Serial.end();
Serial1.end();
rpiUART0.end();
rpiUART5.end();
// Setup serial ports
if (uartConfig.Serial) {
Serial.begin(115200);
}
if (uartConfig.Serial1) {
Serial1.begin(115200);
}
if (uartConfig.rpiUART0) {
rpiUART0.begin(115200);
}
if (uartConfig.rpiUART5) {
rpiUART5.begin(115200);
}
}
// Timer handler
void TC5_Handler (void) {
if(ledState == true) {
digitalWrite(PIN_BOARD_LED, HIGH);
} else {
digitalWrite(PIN_BOARD_LED, LOW);
}
ledState = !ledState;
TC5->COUNT16.INTFLAG.bit.MC0 = 1; //Writing a 1 to INTFLAG.bit.MC0 clears the interrupt so that it will run again
}
//Configures the TC to generate output events at the sample frequency.
//Configures the TC in Frequency Generation mode, with an event output once
//each time the audio sample frequency period expires.
void timerConfigure(int sampleRate) {
// select the generic clock generator used as source to the generic clock multiplexer
GCLK->CLKCTRL.reg = (uint16_t) (GCLK_CLKCTRL_CLKEN | GCLK_CLKCTRL_GEN_GCLK0 | GCLK_CLKCTRL_ID(GCM_TC4_TC5)) ;
while (GCLK->STATUS.bit.SYNCBUSY);
timerReset(); //reset TC5
// Set Timer counter 5 Mode to 16 bits, it will become a 16bit counter ('mode1' in the datasheet)
TC5->COUNT16.CTRLA.reg |= TC_CTRLA_MODE_COUNT16;
// Set TC5 waveform generation mode to 'match frequency'
TC5->COUNT16.CTRLA.reg |= TC_CTRLA_WAVEGEN_MFRQ;
//set prescaler
//the clock normally counts at the GCLK_TC frequency, but we can set it to divide that frequency to slow it down
//you can use different prescaler divisons here like TC_CTRLA_PRESCALER_DIV1 to get a different range
TC5->COUNT16.CTRLA.reg |= TC_CTRLA_PRESCALER_DIV1024 | TC_CTRLA_ENABLE; //it will divide GCLK_TC frequency by 1024
//set the compare-capture register.
//The counter will count up to this value (it's a 16bit counter so we use uint16_t)
//this is how we fine-tune the frequency, make it count to a lower or higher value
//system clock should be 1MHz (8MHz/8) at Reset by default
TC5->COUNT16.CC[0].reg = (uint16_t) (SystemCoreClock / sampleRate);
while (timerIsSyncing());
// Configure interrupt request
NVIC_DisableIRQ(TC5_IRQn);
NVIC_ClearPendingIRQ(TC5_IRQn);
NVIC_SetPriority(TC5_IRQn, 0);
NVIC_EnableIRQ(TC5_IRQn);
// Enable the TC5 interrupt request
TC5->COUNT16.INTENSET.bit.MC0 = 1;
while (timerIsSyncing()); //wait until TC5 is done syncing
}
//Function that is used to check if TC5 is done syncing
//returns true when it is done syncing
bool timerIsSyncing() {
return TC5->COUNT16.STATUS.reg & TC_STATUS_SYNCBUSY;
}
//This function enables TC5 and waits for it to be ready
void timerStartCounter() {
TC5->COUNT16.CTRLA.reg |= TC_CTRLA_ENABLE; //set the CTRLA register
while (timerIsSyncing()); //wait until snyc'd
}
//Reset TC5
void timerReset() {
TC5->COUNT16.CTRLA.reg = TC_CTRLA_SWRST;
while (timerIsSyncing());
while (TC5->COUNT16.CTRLA.bit.SWRST);
}
//disable TC5
void timerDisable() {
TC5->COUNT16.CTRLA.reg &= ~TC_CTRLA_ENABLE;
while (timerIsSyncing());
}
Reference in New Issue View Git Blame Copy Permalink