// USART0 initialization
// Communication Parameters: 8 Data, 1 Stop, No Parity
// USART0 Receiver: Off
// USART0 Transmitter: On
// USART0 Mode: Asynchronous
// USART0 Baud Rate: 38400
UCSR0A=0x00;
UCSR0B=0x48;
UCSR0C=0x06;
UBRR0H=0x00;
UBRR0L=0x0C;
// USART1 initialization
// Communication Parameters: 8 Data, 1 Stop, No Parity
// USART1 Receiver: On
// USART1 Transmitter: On
// USART1 Mode: Asynchronous
// USART1 Baud Rate: 38400
UCSR1A=0x00;
UCSR1B=0xD8;
UCSR1C=0x06;
UBRR1H=0x00;
UBRR1L=0x0C;
Actually if you could stop writing like a stupid it would be much appreciated. If you can´t bother to write a few more letters, why should anyone bother reading it and helping you?nd wht kinda settings u meant.??m sorry if i sound lyk a stupid..
/*****************************************************
This program was produced by the
CodeWizardAVR V1.25.3 Standard
Automatic Program Generator
Project :
Version :
Date : 05.03.2012
Author :
Company :
Comments:
Chip type : ATmega128
Program type : Application
Clock frequency : 8,000000 MHz
Memory model : Small
External SRAM size : 0
Data Stack size : 1024
*****************************************************/
#include <mega128.h>
#include <string.h>
#define RXB8 1
#define TXB8 0
#define UPE 2
#define OVR 3
#define FE 4
#define UDRE 5
#define RXC 7
#define FRAMING_ERROR (1<<FE)
#define PARITY_ERROR (1<<UPE)
#define DATA_OVERRUN (1<<OVR)
#define DATA_REGISTER_EMPTY (1<<UDRE)
#define RX_COMPLETE (1<<RXC)
// USART0 Receiver buffer
#define RX_BUFFER_SIZE0 64
char rx_buffer0[RX_BUFFER_SIZE0];
#if RX_BUFFER_SIZE0<256
unsigned char rx_wr_index0,rx_rd_index0,rx_counter0;
#else
unsigned int rx_wr_index0,rx_rd_index0,rx_counter0;
#endif
// This flag is set on USART0 Receiver buffer overflow
bit rx_buffer_overflow0;
// USART0 Receiver interrupt service routine
interrupt [USART0_RXC] void usart0_rx_isr(void)
{
char status,data;
status=UCSR0A;
data=UDR0;
if ((status & (FRAMING_ERROR | PARITY_ERROR | DATA_OVERRUN))==0)
{
rx_buffer0[rx_wr_index0]=data;
if (++rx_wr_index0 == RX_BUFFER_SIZE0) rx_wr_index0=0;
if (++rx_counter0 == RX_BUFFER_SIZE0)
{
rx_counter0=0;
rx_buffer_overflow0=1;
};
};
}
#ifndef _DEBUG_TERMINAL_IO_
// Get a character from the USART0 Receiver buffer
#define _ALTERNATE_GETCHAR_
#pragma used+
char getchar(void)
{
char data;
while (rx_counter0==0);
data=rx_buffer0[rx_rd_index0];
if (++rx_rd_index0 == RX_BUFFER_SIZE0) rx_rd_index0=0;
#asm("cli")
--rx_counter0;
#asm("sei")
return data;
}
#pragma used-
#endif
// USART0 Transmitter buffer
#define TX_BUFFER_SIZE0 64
char tx_buffer0[TX_BUFFER_SIZE0];
#if TX_BUFFER_SIZE0<256
unsigned char tx_wr_index0,tx_rd_index0,tx_counter0;
#else
unsigned int tx_wr_index0,tx_rd_index0,tx_counter0;
#endif
// USART0 Transmitter interrupt service routine
interrupt [USART0_TXC] void usart0_tx_isr(void)
{
if (tx_counter0)
{
--tx_counter0;
UDR0=tx_buffer0[tx_rd_index0];
if (++tx_rd_index0 == TX_BUFFER_SIZE0) tx_rd_index0=0;
};
}
#ifndef _DEBUG_TERMINAL_IO_
// Write a character to the USART0 Transmitter buffer
#define _ALTERNATE_PUTCHAR_
#pragma used+
void putchar(char c)
{
while (tx_counter0 == TX_BUFFER_SIZE0);
#asm("cli")
if (tx_counter0 || ((UCSR0A & DATA_REGISTER_EMPTY)==0))
{
tx_buffer0[tx_wr_index0]=c;
if (++tx_wr_index0 == TX_BUFFER_SIZE0) tx_wr_index0=0;
++tx_counter0;
}
else
UDR0=c;
#asm("sei")
}
#pragma used-
#endif
// Standard Input/Output functions
#include <stdio.h>
// Declare your global variables here
void main(void)
{
// Declare your local variables here
unsigned char string[56],uc_i=0;
// Input/Output Ports initialization
// Port A initialization
// Func7=In Func6=In Func5=In Func4=In Func3=In Func2=In Func1=In Func0=In
// State7=T State6=T State5=T State4=T State3=T State2=T State1=T State0=T
PORTA=0x00;
DDRA=0x00;
// Port B initialization
// Func7=In Func6=In Func5=In Func4=In Func3=In Func2=In Func1=In Func0=In
// State7=T State6=T State5=T State4=T State3=T State2=T State1=T State0=T
PORTB=0x00;
DDRB=0x00;
// Port C initialization
// Func7=In Func6=In Func5=In Func4=In Func3=In Func2=In Func1=In Func0=In
// State7=T State6=T State5=T State4=T State3=T State2=T State1=T State0=T
PORTC=0x00;
DDRC=0x00;
// Port D initialization
// Func7=In Func6=In Func5=In Func4=In Func3=In Func2=In Func1=In Func0=In
// State7=T State6=T State5=T State4=T State3=T State2=T State1=T State0=T
PORTD=0x00;
DDRD=0x00;
// Port E initialization
// Func7=In Func6=In Func5=In Func4=In Func3=In Func2=In Func1=In Func0=In
// State7=T State6=T State5=T State4=T State3=T State2=T State1=T State0=T
PORTE=0x00;
DDRE=0x00;
// Port F initialization
// Func7=In Func6=In Func5=In Func4=In Func3=In Func2=In Func1=In Func0=In
// State7=T State6=T State5=T State4=T State3=T State2=T State1=T State0=T
PORTF=0x00;
DDRF=0x00;
// Port G initialization
// Func4=In Func3=In Func2=In Func1=In Func0=In
// State4=T State3=T State2=T State1=T State0=T
PORTG=0x00;
DDRG=0x00;
// Timer/Counter 0 initialization
// Clock source: System Clock
// Clock value: Timer 0 Stopped
// Mode: Normal top=FFh
// OC0 output: Disconnected
ASSR=0x00;
TCCR0=0x00;
TCNT0=0x00;
OCR0=0x00;
// Timer/Counter 1 initialization
// Clock source: System Clock
// Clock value: Timer 1 Stopped
// Mode: Normal top=FFFFh
// OC1A output: Discon.
// OC1B output: Discon.
// OC1C output: Discon.
// Noise Canceler: Off
// Input Capture on Falling Edge
// Timer 1 Overflow Interrupt: Off
// Input Capture Interrupt: Off
// Compare A Match Interrupt: Off
// Compare B Match Interrupt: Off
// Compare C Match Interrupt: Off
TCCR1A=0x00;
TCCR1B=0x00;
TCNT1H=0x00;
TCNT1L=0x00;
ICR1H=0x00;
ICR1L=0x00;
OCR1AH=0x00;
OCR1AL=0x00;
OCR1BH=0x00;
OCR1BL=0x00;
OCR1CH=0x00;
OCR1CL=0x00;
// Timer/Counter 2 initialization
// Clock source: System Clock
// Clock value: Timer 2 Stopped
// Mode: Normal top=FFh
// OC2 output: Disconnected
TCCR2=0x00;
TCNT2=0x00;
OCR2=0x00;
// Timer/Counter 3 initialization
// Clock source: System Clock
// Clock value: Timer 3 Stopped
// Mode: Normal top=FFFFh
// Noise Canceler: Off
// Input Capture on Falling Edge
// OC3A output: Discon.
// OC3B output: Discon.
// OC3C output: Discon.
// Timer 3 Overflow Interrupt: Off
// Input Capture Interrupt: Off
// Compare A Match Interrupt: Off
// Compare B Match Interrupt: Off
// Compare C Match Interrupt: Off
TCCR3A=0x00;
TCCR3B=0x00;
TCNT3H=0x00;
TCNT3L=0x00;
ICR3H=0x00;
ICR3L=0x00;
OCR3AH=0x00;
OCR3AL=0x00;
OCR3BH=0x00;
OCR3BL=0x00;
OCR3CH=0x00;
OCR3CL=0x00;
// External Interrupt(s) initialization
// INT0: Off
// INT1: Off
// INT2: Off
// INT3: Off
// INT4: Off
// INT5: Off
// INT6: Off
// INT7: Off
EICRA=0x00;
EICRB=0x00;
EIMSK=0x00;
// Timer(s)/Counter(s) Interrupt(s) initialization
TIMSK=0x00;
ETIMSK=0x00;
// USART0 initialization
// Communication Parameters: 8 Data, 1 Stop, No Parity
// USART0 Receiver: On
// USART0 Transmitter: On
// USART0 Mode: Asynchronous
// USART0 Baud rate: 9600
UCSR0A=0x00;
UCSR0B=0xD8;
UCSR0C=0x06;
UBRR0H=0x00;
UBRR0L=0x33;
// Analog Comparator initialization
// Analog Comparator: Off
// Analog Comparator Input Capture by Timer/Counter 1: Off
ACSR=0x80;
SFIOR=0x00;
// Global enable interrupts
#asm("sei")
while (1)
{
strcpyf(string,"Hello World");
for(uc_i=0;uc_i<strlen(string);uc_i++)
{
putchar(string[uc_i]);
}
// Place your code here
};
}
It allows you to specify the following communication modes:
· Asynchronous
· Synchronous Master, with the UCSRC register's UCPOL bit set to 0
· Synchronous Master, with the UCSRC register's UCPOL bit set to 1
· Synchronous Slave, with the UCSRC register's UCPOL bit set to 0
· Synchronous Slave, with the UCSRC register's UCPOL bit set to 1.
The serial communication is realized using the Standard Input/Output Functions getchar, gets, scanf, putchar, puts and printf.
For interrupt driven serial communication, CodeWizardAVR automatically redefines the basic getchar and putchar functions.
The receiver buffer is implemented using the global array rx_buffer.
The global variable rx_wr_index is the rx_buffer array index used for writing received characters in the buffer.
The global variable rx_rd_index is the rx_buffer array index used for reading received characters from the buffer by the getchar function.
The global variable rx_counter contains the number of characters received in rx_buffer and not yet read by the getchar function.
If the receiver buffers overflows the rx_buffer_overflow global bit variable will be set.
The transmitter buffer is implemented using the global array tx_buffer.
The global variable tx_wr_index is the tx_buffer array index used for writing in the buffer the characters to be transmitted.
The global variable tx_rd_index is the tx_buffer array index used for reading from the buffer the characters to be transmitted by the putchar function.
The global variable tx_counter contains the number of characters from tx_buffer not yet transmitted by the interrupt system.
For devices with 2 UARTs, respectively 2 USARTs, there will be two tabs present: UART0 and UART1, respectively USART0 and USART1.
The functions of configuration check and list boxes will be the same as described above.
The UART0 (USART0) will use the normal putchar and getchar functions.
In case of interrupt driven buffered communication, UART0 (USART0) will use the following variables:
rx_buffer0, rx_wr_index0, rx_rd_index0, rx_counter0, rx_buffer_overflow0,
tx_buffer0, tx_wr_index0, tx_rd_index0, tx_counter0.
The UART1 (USART1) will use the putchar1 and getchar1 functions.
In case of interrupt driven buffered communication, UART1 (USART1) will use the following variables:
rx_buffer1, rx_wr_index1, rx_rd_index1, rx_counter1, rx_buffer_overflow1,
tx_buffer1, tx_wr_index1, tx_rd_index1, tx_counter1.
All serial I/O using functions declared in stdio.h, will be done using UART0 (USART0).
The last Bit only could 0 or 1I didnt understand the last bit...will you please explain it to me..??thanks
That is the Interrupt driven one.what do i have to change in the code to make it interrupt.?
No! You can do it by yourself.did u try it for atmega 1284p?
I think thats OKUBRR1H = ( BAUD_PRESCALE >> 8);// Load upper 8- bits of the baud rate value into the high byte of
the UBRR register
BAUD_PRESCALE is a 16Bit Variable, UBRR1L is a 8Bit Variable.UBRR1L = BAUD_PRESCALE ; // Load lower 8- bits of the baud rate value into the low byte of the
UBRR register
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