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Serial.cpp
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Serial.cpp
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#include "Arduino.h"
#include "config.h"
#include "def.h"
#include "Serial.h"
#include "MultiWii.h"
static volatile uint8_t serialHeadRX[UART_NUMBER],serialTailRX[UART_NUMBER];
static uint8_t serialBufferRX[RX_BUFFER_SIZE][UART_NUMBER];
static volatile uint8_t serialHeadTX[UART_NUMBER],serialTailTX[UART_NUMBER];
static uint8_t serialBufferTX[TX_BUFFER_SIZE][UART_NUMBER];
// *******************************************************
// For Teensy 2.0, these function emulate the API used for ProMicro
// it cant have the same name as in the arduino API because it wont compile for the promini (eaven if it will be not compiled)
// *******************************************************
#if defined(TEENSY20)
unsigned char T_USB_Available(){
int n = Serial.available();
if (n > 255) n = 255;
return n;
}
#endif
// *******************************************************
// Interrupt driven UART transmitter - using a ring buffer
// *******************************************************
#if defined(PROMINI) || defined(MEGA)
#if defined(PROMINI)
ISR(USART_UDRE_vect) { // Serial 0 on a PROMINI
#endif
#if defined(MEGA)
ISR(USART0_UDRE_vect) { // Serial 0 on a MEGA
#endif
uint8_t t = serialTailTX[0];
if (serialHeadTX[0] != t) {
if (++t >= TX_BUFFER_SIZE) t = 0;
UDR0 = serialBufferTX[t][0]; // Transmit next byte in the ring
serialTailTX[0] = t;
}
if (t == serialHeadTX[0]) UCSR0B &= ~(1<<UDRIE0); // Check if all data is transmitted . if yes disable transmitter UDRE interrupt
}
#endif
#if defined(MEGA) || defined(PROMICRO)
ISR(USART1_UDRE_vect) { // Serial 1 on a MEGA or on a PROMICRO
uint8_t t = serialTailTX[1];
if (serialHeadTX[1] != t) {
if (++t >= TX_BUFFER_SIZE) t = 0;
UDR1 = serialBufferTX[t][1]; // Transmit next byte in the ring
serialTailTX[1] = t;
}
if (t == serialHeadTX[1]) UCSR1B &= ~(1<<UDRIE1);
}
#endif
#if defined(MEGA)
ISR(USART2_UDRE_vect) { // Serial 2 on a MEGA
uint8_t t = serialTailTX[2];
if (serialHeadTX[2] != t) {
if (++t >= TX_BUFFER_SIZE) t = 0;
UDR2 = serialBufferTX[t][2];
serialTailTX[2] = t;
}
if (t == serialHeadTX[2]) UCSR2B &= ~(1<<UDRIE2);
}
ISR(USART3_UDRE_vect) { // Serial 3 on a MEGA
uint8_t t = serialTailTX[3];
if (serialHeadTX[3] != t) {
if (++t >= TX_BUFFER_SIZE) t = 0;
UDR3 = serialBufferTX[t][3];
serialTailTX[3] = t;
}
if (t == serialHeadTX[3]) UCSR3B &= ~(1<<UDRIE3);
}
#endif
void UartSendData(uint8_t port) {
#if defined(PROMINI)
UCSR0B |= (1<<UDRIE0);
#endif
#if defined(PROMICRO)
switch (port) {
case 0:
while(serialHeadTX[0] != serialTailTX[0]) {
if (++serialTailTX[0] >= TX_BUFFER_SIZE) serialTailTX[0] = 0;
#if !defined(TEENSY20)
USB_Send(USB_CDC_TX,serialBufferTX[serialTailTX[0]],1);
#else
Serial.write(serialBufferTX[serialTailTX[0]],1);
#endif
}
break;
case 1: UCSR1B |= (1<<UDRIE1); break;
}
#endif
#if defined(MEGA)
switch (port) {
case 0: UCSR0B |= (1<<UDRIE0); break;
case 1: UCSR1B |= (1<<UDRIE1); break;
case 2: UCSR2B |= (1<<UDRIE2); break;
case 3: UCSR3B |= (1<<UDRIE3); break;
}
#endif
}
#if defined(GPS_SERIAL)
bool SerialTXfree(uint8_t port) {
return (serialHeadTX[port] == serialTailTX[port]);
}
#endif
void SerialOpen(uint8_t port, uint32_t baud) {
uint8_t h = ((F_CPU / 4 / baud -1) / 2) >> 8;
uint8_t l = ((F_CPU / 4 / baud -1) / 2);
switch (port) {
#if defined(PROMINI)
case 0: UCSR0A = (1<<U2X0); UBRR0H = h; UBRR0L = l; UCSR0B |= (1<<RXEN0)|(1<<TXEN0)|(1<<RXCIE0); break;
#endif
#if defined(PROMICRO)
#if (ARDUINO >= 100) && !defined(TEENSY20)
case 0: UDIEN &= ~(1<<SOFE); break;// disable the USB frame interrupt of arduino (it causes strong jitter and we dont need it)
#endif
case 1: UCSR1A = (1<<U2X1); UBRR1H = h; UBRR1L = l; UCSR1B |= (1<<RXEN1)|(1<<TXEN1)|(1<<RXCIE1); break;
#endif
#if defined(MEGA)
case 0: UCSR0A = (1<<U2X0); UBRR0H = h; UBRR0L = l; UCSR0B |= (1<<RXEN0)|(1<<TXEN0)|(1<<RXCIE0); break;
case 1: UCSR1A = (1<<U2X1); UBRR1H = h; UBRR1L = l; UCSR1B |= (1<<RXEN1)|(1<<TXEN1)|(1<<RXCIE1); break;
case 2: UCSR2A = (1<<U2X2); UBRR2H = h; UBRR2L = l; UCSR2B |= (1<<RXEN2)|(1<<TXEN2)|(1<<RXCIE2); break;
case 3: UCSR3A = (1<<U2X3); UBRR3H = h; UBRR3L = l; UCSR3B |= (1<<RXEN3)|(1<<TXEN3)|(1<<RXCIE3); break;
#endif
}
}
void SerialEnd(uint8_t port) {
switch (port) {
#if defined(PROMINI)
case 0: UCSR0B &= ~((1<<RXEN0)|(1<<TXEN0)|(1<<RXCIE0)|(1<<UDRIE0)); break;
#endif
#if defined(PROMICRO)
case 1: UCSR1B &= ~((1<<RXEN1)|(1<<TXEN1)|(1<<RXCIE1)|(1<<UDRIE1)); break;
#endif
#if defined(MEGA)
case 0: UCSR0B &= ~((1<<RXEN0)|(1<<TXEN0)|(1<<RXCIE0)|(1<<UDRIE0)); break;
case 1: UCSR1B &= ~((1<<RXEN1)|(1<<TXEN1)|(1<<RXCIE1)|(1<<UDRIE1)); break;
case 2: UCSR2B &= ~((1<<RXEN2)|(1<<TXEN2)|(1<<RXCIE2)|(1<<UDRIE2)); break;
case 3: UCSR3B &= ~((1<<RXEN3)|(1<<TXEN3)|(1<<RXCIE3)|(1<<UDRIE3)); break;
#endif
}
}
// we don't care about ring buffer overflow (head->tail) to avoid a test condition : data is lost anyway if it happens
void store_uart_in_buf(uint8_t data, uint8_t portnum) {
#if defined(SPEKTRUM) || defined(SBUS) || defined(SUMD)
if (portnum == RX_SERIAL_PORT) {
if (!spekFrameFlags) {
sei();
uint32_t spekTimeNow = (timer0_overflow_count << 8) * (64 / clockCyclesPerMicrosecond()); //Move timer0_overflow_count into registers so we don't touch a volatile twice
uint32_t spekInterval = spekTimeNow - spekTimeLast; //timer0_overflow_count will be slightly off because of the way the Arduino core timer interrupt handler works; that is acceptable for this use. Using the core variable avoids an expensive call to millis() or micros()
spekTimeLast = spekTimeNow;
if (spekInterval > 2500) { //Potential start of a Spektrum frame, they arrive every 11 or every 22 ms. Mark it, and clear the buffer.
serialTailRX[portnum] = 0;
serialHeadRX[portnum] = 0;
spekFrameFlags = 0x01;
}
cli();
}
}
#endif
uint8_t h = serialHeadRX[portnum];
serialBufferRX[h++][portnum] = data;
if (h >= RX_BUFFER_SIZE) h = 0;
serialHeadRX[portnum] = h;
}
#if defined(PROMINI)
ISR(USART_RX_vect) { store_uart_in_buf(UDR0, 0); }
#endif
#if defined(PROMICRO)
ISR(USART1_RX_vect) { store_uart_in_buf(UDR1, 1); }
#endif
#if defined(MEGA)
ISR(USART0_RX_vect) { store_uart_in_buf(UDR0, 0); }
ISR(USART1_RX_vect) { store_uart_in_buf(UDR1, 1); }
ISR(USART2_RX_vect) { store_uart_in_buf(UDR2, 2); }
ISR(USART3_RX_vect) { store_uart_in_buf(UDR3, 3); }
#endif
uint8_t SerialRead(uint8_t port) {
#if defined(PROMICRO)
#if defined(TEENSY20)
if(port == 0) return Serial.read();
#else
#if (ARDUINO >= 100)
if(port == 0) USB_Flush(USB_CDC_TX);
#endif
if(port == 0) return USB_Recv(USB_CDC_RX);
#endif
#endif
uint8_t t = serialTailRX[port];
uint8_t c = serialBufferRX[t][port];
if (serialHeadRX[port] != t) {
if (++t >= RX_BUFFER_SIZE) t = 0;
serialTailRX[port] = t;
}
return c;
}
#if defined(SPEKTRUM)
uint8_t SerialPeek(uint8_t port) {
uint8_t c = serialBufferRX[serialTailRX[port]][port];
if ((serialHeadRX[port] != serialTailRX[port])) return c; else return 0;
}
#endif
uint8_t SerialAvailable(uint8_t port) {
#if defined(PROMICRO)
#if !defined(TEENSY20)
if(port == 0) return USB_Available(USB_CDC_RX);
#else
if(port == 0) return T_USB_Available();
#endif
#endif
return ((uint8_t)(serialHeadRX[port] - serialTailRX[port]))%RX_BUFFER_SIZE;
}
uint8_t SerialUsedTXBuff(uint8_t port) {
return ((uint8_t)(serialHeadTX[port] - serialTailTX[port]))%TX_BUFFER_SIZE;
}
void SerialSerialize(uint8_t port,uint8_t a) {
uint8_t t = serialHeadTX[port];
if (++t >= TX_BUFFER_SIZE) t = 0;
serialBufferTX[t][port] = a;
serialHeadTX[port] = t;
}
void SerialWrite(uint8_t port,uint8_t c){
SerialSerialize(port,c);UartSendData(port);
}