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authorDavid A. Mellis <d.mellis@arduino.cc>2008-10-11 15:20:39 +0000
committerDavid A. Mellis <d.mellis@arduino.cc>2008-10-11 15:20:39 +0000
commit3898f82e7da63ee529eaaecd52f4cc78191319e9 (patch)
treee94a206c8840bc563c67e461cd70f2f17cd7f755
parent434d786347333b7fb7ed664b5bba76bb72608e1f (diff)
Reindenting the ATmega168 bootloader file. It was a mess (and still is somewhat of one).
-rwxr-xr-xbootloaders/atmega168/ATmegaBOOT_168.c1030
1 files changed, 513 insertions, 517 deletions
diff --git a/bootloaders/atmega168/ATmegaBOOT_168.c b/bootloaders/atmega168/ATmegaBOOT_168.c
index 7bbf24e..f1c1cdf 100755
--- a/bootloaders/atmega168/ATmegaBOOT_168.c
+++ b/bootloaders/atmega168/ATmegaBOOT_168.c
@@ -218,18 +218,18 @@ void flash_led(uint8_t);
/* some variables */
union address_union {
- uint16_t word;
- uint8_t byte[2];
+ uint16_t word;
+ uint8_t byte[2];
} address;
union length_union {
- uint16_t word;
- uint8_t byte[2];
+ uint16_t word;
+ uint8_t byte[2];
} length;
struct flags_struct {
- unsigned eeprom : 1;
- unsigned rampz : 1;
+ unsigned eeprom : 1;
+ unsigned rampz : 1;
} flags;
uint8_t buff[256];
@@ -248,140 +248,140 @@ void (*app_start)(void) = 0x0000;
/* main program starts here */
int main(void)
{
- uint8_t ch,ch2;
- uint16_t w;
+ uint8_t ch,ch2;
+ uint16_t w;
#ifdef WATCHDOG_MODS
- ch = MCUSR;
- MCUSR = 0;
+ ch = MCUSR;
+ MCUSR = 0;
- WDTCSR |= _BV(WDCE) | _BV(WDE);
- WDTCSR = 0;
+ WDTCSR |= _BV(WDCE) | _BV(WDE);
+ WDTCSR = 0;
- // Check if the WDT was used to reset, in which case we dont bootload and skip straight to the code. woot.
- if (! (ch & _BV(EXTRF))) // if its a not an external reset...
- app_start(); // skip bootloader
+ // Check if the WDT was used to reset, in which case we dont bootload and skip straight to the code. woot.
+ if (! (ch & _BV(EXTRF))) // if its a not an external reset...
+ app_start(); // skip bootloader
#else
- asm volatile("nop\n\t");
+ asm volatile("nop\n\t");
#endif
- /* set pin direction for bootloader pin and enable pullup */
- /* for ATmega128, two pins need to be initialized */
+ /* set pin direction for bootloader pin and enable pullup */
+ /* for ATmega128, two pins need to be initialized */
#ifdef __AVR_ATmega128__
- BL_DDR &= ~_BV(BL0);
- BL_DDR &= ~_BV(BL1);
- BL_PORT |= _BV(BL0);
- BL_PORT |= _BV(BL1);
+ BL_DDR &= ~_BV(BL0);
+ BL_DDR &= ~_BV(BL1);
+ BL_PORT |= _BV(BL0);
+ BL_PORT |= _BV(BL1);
#else
- /* We run the bootloader regardless of the state of this pin. Thus, don't
- put it in a different state than the other pins. --DAM, 070709
- BL_DDR &= ~_BV(BL);
- BL_PORT |= _BV(BL);
- */
+ /* We run the bootloader regardless of the state of this pin. Thus, don't
+ put it in a different state than the other pins. --DAM, 070709
+ BL_DDR &= ~_BV(BL);
+ BL_PORT |= _BV(BL);
+ */
#endif
#ifdef __AVR_ATmega128__
- /* check which UART should be used for booting */
- if(bit_is_clear(BL_PIN, BL0)) {
- bootuart = 1;
- }
- else if(bit_is_clear(BL_PIN, BL1)) {
- bootuart = 2;
- }
+ /* check which UART should be used for booting */
+ if(bit_is_clear(BL_PIN, BL0)) {
+ bootuart = 1;
+ }
+ else if(bit_is_clear(BL_PIN, BL1)) {
+ bootuart = 2;
+ }
#endif
- /* check if flash is programmed already, if not start bootloader anyway */
- if(pgm_read_byte_near(0x0000) != 0xFF) {
+ /* check if flash is programmed already, if not start bootloader anyway */
+ if(pgm_read_byte_near(0x0000) != 0xFF) {
#ifdef __AVR_ATmega128__
- /* no UART was selected, start application */
- if(!bootuart) {
- app_start();
- }
+ /* no UART was selected, start application */
+ if(!bootuart) {
+ app_start();
+ }
#else
- /* check if bootloader pin is set low */
- /* we don't start this part neither for the m8, nor m168 */
- //if(bit_is_set(BL_PIN, BL)) {
- // app_start();
- // }
+ /* check if bootloader pin is set low */
+ /* we don't start this part neither for the m8, nor m168 */
+ //if(bit_is_set(BL_PIN, BL)) {
+ // app_start();
+ //}
#endif
- }
+ }
-#ifdef __AVR_ATmega128__
- /* no bootuart was selected, default to uart 0 */
- if(!bootuart) {
- bootuart = 1;
- }
+#ifdef __AVR_ATmega128__
+ /* no bootuart was selected, default to uart 0 */
+ if(!bootuart) {
+ bootuart = 1;
+ }
#endif
- /* initialize UART(s) depending on CPU defined */
+ /* initialize UART(s) depending on CPU defined */
#ifdef __AVR_ATmega128__
- if(bootuart == 1) {
- UBRR0L = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
- UBRR0H = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
- UCSR0A = 0x00;
- UCSR0C = 0x06;
- UCSR0B = _BV(TXEN0)|_BV(RXEN0);
- }
- if(bootuart == 2) {
- UBRR1L = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
- UBRR1H = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
- UCSR1A = 0x00;
- UCSR1C = 0x06;
- UCSR1B = _BV(TXEN1)|_BV(RXEN1);
- }
+ if(bootuart == 1) {
+ UBRR0L = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
+ UBRR0H = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
+ UCSR0A = 0x00;
+ UCSR0C = 0x06;
+ UCSR0B = _BV(TXEN0)|_BV(RXEN0);
+ }
+ if(bootuart == 2) {
+ UBRR1L = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
+ UBRR1H = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
+ UCSR1A = 0x00;
+ UCSR1C = 0x06;
+ UCSR1B = _BV(TXEN1)|_BV(RXEN1);
+ }
#elif defined __AVR_ATmega163__
- UBRR = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
- UBRRHI = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
- UCSRA = 0x00;
- UCSRB = _BV(TXEN)|_BV(RXEN);
+ UBRR = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
+ UBRRHI = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
+ UCSRA = 0x00;
+ UCSRB = _BV(TXEN)|_BV(RXEN);
#elif defined __AVR_ATmega168__
- UBRR0L = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
- UBRR0H = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
- UCSR0B = (1<<RXEN0) | (1<<TXEN0);
- UCSR0C = (1<<UCSZ00) | (1<<UCSZ01);
-
- /* Enable internal pull-up resistor on pin D0 (RX), in order
- to supress line noise that prevents the bootloader from
- timing out (DAM: 20070509) */
- DDRD &= ~_BV(PIND0);
- PORTD |= _BV(PIND0);
+ UBRR0L = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
+ UBRR0H = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
+ UCSR0B = (1<<RXEN0) | (1<<TXEN0);
+ UCSR0C = (1<<UCSZ00) | (1<<UCSZ01);
+
+ /* Enable internal pull-up resistor on pin D0 (RX), in order
+ to supress line noise that prevents the bootloader from
+ timing out (DAM: 20070509) */
+ DDRD &= ~_BV(PIND0);
+ PORTD |= _BV(PIND0);
#elif defined __AVR_ATmega8__
- /* m8 */
- UBRRH = (((F_CPU/BAUD_RATE)/16)-1)>>8; // set baud rate
- UBRRL = (((F_CPU/BAUD_RATE)/16)-1);
- UCSRB = (1<<RXEN)|(1<<TXEN); // enable Rx & Tx
- UCSRC = (1<<URSEL)|(1<<UCSZ1)|(1<<UCSZ0); // config USART; 8N1
+ /* m8 */
+ UBRRH = (((F_CPU/BAUD_RATE)/16)-1)>>8; // set baud rate
+ UBRRL = (((F_CPU/BAUD_RATE)/16)-1);
+ UCSRB = (1<<RXEN)|(1<<TXEN); // enable Rx & Tx
+ UCSRC = (1<<URSEL)|(1<<UCSZ1)|(1<<UCSZ0); // config USART; 8N1
#else
- /* m16,m32,m169,m8515,m8535 */
- UBRRL = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
- UBRRH = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
- UCSRA = 0x00;
- UCSRC = 0x06;
- UCSRB = _BV(TXEN)|_BV(RXEN);
+ /* m16,m32,m169,m8515,m8535 */
+ UBRRL = (uint8_t)(F_CPU/(BAUD_RATE*16L)-1);
+ UBRRH = (F_CPU/(BAUD_RATE*16L)-1) >> 8;
+ UCSRA = 0x00;
+ UCSRC = 0x06;
+ UCSRB = _BV(TXEN)|_BV(RXEN);
#endif
- /* set LED pin as output */
- LED_DDR |= _BV(LED);
+ /* set LED pin as output */
+ LED_DDR |= _BV(LED);
- /* flash onboard LED to signal entering of bootloader */
+ /* flash onboard LED to signal entering of bootloader */
#ifdef __AVR_ATmega128__
- // 4x for UART0, 5x for UART1
- flash_led(NUM_LED_FLASHES + bootuart);
+ // 4x for UART0, 5x for UART1
+ flash_led(NUM_LED_FLASHES + bootuart);
#else
- flash_led(NUM_LED_FLASHES);
+ flash_led(NUM_LED_FLASHES);
#endif
-
- /* 20050803: by DojoCorp, this is one of the parts provoking the
- system to stop listening, cancelled from the original */
- //putch('\0');
+
+ /* 20050803: by DojoCorp, this is one of the parts provoking the
+ system to stop listening, cancelled from the original */
+ //putch('\0');
- /* forever loop */
- for (;;) {
+ /* forever loop */
+ for (;;) {
/* get character from UART */
ch = getch();
@@ -390,7 +390,7 @@ int main(void)
/* Hello is anyone home ? */
if(ch=='0') {
- nothing_response();
+ nothing_response();
}
@@ -398,76 +398,76 @@ int main(void)
/* Not using PROGMEM string due to boot block in m128 being beyond 64kB boundry */
/* Would need to selectively manipulate RAMPZ, and it's only 9 characters anyway so who cares. */
else if(ch=='1') {
- if (getch() == ' ') {
- putch(0x14);
- putch('A');
- putch('V');
- putch('R');
- putch(' ');
- putch('I');
- putch('S');
- putch('P');
- putch(0x10);
- } else {
- if (++error_count == MAX_ERROR_COUNT)
- app_start();
- }
+ if (getch() == ' ') {
+ putch(0x14);
+ putch('A');
+ putch('V');
+ putch('R');
+ putch(' ');
+ putch('I');
+ putch('S');
+ putch('P');
+ putch(0x10);
+ } else {
+ if (++error_count == MAX_ERROR_COUNT)
+ app_start();
+ }
}
/* AVR ISP/STK500 board commands DON'T CARE so default nothing_response */
else if(ch=='@') {
- ch2 = getch();
- if (ch2>0x85) getch();
- nothing_response();
+ ch2 = getch();
+ if (ch2>0x85) getch();
+ nothing_response();
}
/* AVR ISP/STK500 board requests */
else if(ch=='A') {
- ch2 = getch();
- if(ch2==0x80) byte_response(HW_VER); // Hardware version
- else if(ch2==0x81) byte_response(SW_MAJOR); // Software major version
- else if(ch2==0x82) byte_response(SW_MINOR); // Software minor version
- else if(ch2==0x98) byte_response(0x03); // Unknown but seems to be required by avr studio 3.56
- else byte_response(0x00); // Covers various unnecessary responses we don't care about
+ ch2 = getch();
+ if(ch2==0x80) byte_response(HW_VER); // Hardware version
+ else if(ch2==0x81) byte_response(SW_MAJOR); // Software major version
+ else if(ch2==0x82) byte_response(SW_MINOR); // Software minor version
+ else if(ch2==0x98) byte_response(0x03); // Unknown but seems to be required by avr studio 3.56
+ else byte_response(0x00); // Covers various unnecessary responses we don't care about
}
/* Device Parameters DON'T CARE, DEVICE IS FIXED */
else if(ch=='B') {
- getNch(20);
- nothing_response();
+ getNch(20);
+ nothing_response();
}
/* Parallel programming stuff DON'T CARE */
else if(ch=='E') {
- getNch(5);
- nothing_response();
+ getNch(5);
+ nothing_response();
}
/* Enter programming mode */
else if(ch=='P') {
- nothing_response();
+ nothing_response();
}
/* Leave programming mode */
else if(ch=='Q') {
- nothing_response();
+ nothing_response();
#ifdef WATCHDOG_MODS
- // autoreset via watchdog (sneaky!)
- WDTCSR = _BV(WDE);
- while (1); // 16 ms
+ // autoreset via watchdog (sneaky!)
+ WDTCSR = _BV(WDE);
+ while (1); // 16 ms
#endif
}
/* Erase device, don't care as we will erase one page at a time anyway. */
else if(ch=='R') {
- nothing_response();
+ nothing_response();
}
@@ -475,227 +475,227 @@ int main(void)
/* Perhaps extra address bytes may be added in future to support > 128kB FLASH. */
/* This might explain why little endian was used here, big endian used everywhere else. */
else if(ch=='U') {
- address.byte[0] = getch();
- address.byte[1] = getch();
- nothing_response();
+ address.byte[0] = getch();
+ address.byte[1] = getch();
+ nothing_response();
}
/* Universal SPI programming command, disabled. Would be used for fuses and lock bits. */
else if(ch=='V') {
- getNch(4);
- byte_response(0x00);
+ getNch(4);
+ byte_response(0x00);
}
/* Write memory, length is big endian and is in bytes */
else if(ch=='d') {
- length.byte[1] = getch();
- length.byte[0] = getch();
- flags.eeprom = 0;
- if (getch() == 'E') flags.eeprom = 1;
- for (w=0;w<length.word;w++) {
- buff[w] = getch(); // Store data in buffer, can't keep up with serial data stream whilst programming pages
- }
- if (getch() == ' ') {
- if (flags.eeprom) { //Write to EEPROM one byte at a time
- for(w=0;w<length.word;w++) {
+ length.byte[1] = getch();
+ length.byte[0] = getch();
+ flags.eeprom = 0;
+ if (getch() == 'E') flags.eeprom = 1;
+ for (w=0;w<length.word;w++) {
+ buff[w] = getch(); // Store data in buffer, can't keep up with serial data stream whilst programming pages
+ }
+ if (getch() == ' ') {
+ if (flags.eeprom) { //Write to EEPROM one byte at a time
+ for(w=0;w<length.word;w++) {
#ifdef __AVR_ATmega168__
- while(EECR & (1<<EEPE));
- EEAR = (uint16_t)(void *)address.word;
- EEDR = buff[w];
- EECR |= (1<<EEMPE);
- EECR |= (1<<EEPE);
+ while(EECR & (1<<EEPE));
+ EEAR = (uint16_t)(void *)address.word;
+ EEDR = buff[w];
+ EECR |= (1<<EEMPE);
+ EECR |= (1<<EEPE);
#else
- eeprom_write_byte((void *)address.word,buff[w]);
+ eeprom_write_byte((void *)address.word,buff[w]);
#endif
- address.word++;
- }
- }
- else { //Write to FLASH one page at a time
- if (address.byte[1]>127) address_high = 0x01; //Only possible with m128, m256 will need 3rd address byte. FIXME
- else address_high = 0x00;
+ address.word++;
+ }
+ }
+ else { //Write to FLASH one page at a time
+ if (address.byte[1]>127) address_high = 0x01; //Only possible with m128, m256 will need 3rd address byte. FIXME
+ else address_high = 0x00;
#ifdef __AVR_ATmega128__
- RAMPZ = address_high;
+ RAMPZ = address_high;
#endif
- address.word = address.word << 1; //address * 2 -> byte location
- /* if ((length.byte[0] & 0x01) == 0x01) length.word++; //Even up an odd number of bytes */
- if ((length.byte[0] & 0x01)) length.word++; //Even up an odd number of bytes
- cli(); //Disable interrupts, just to be sure
- // HACKME: EEPE used to be EEWE
- while(bit_is_set(EECR,EEPE)); //Wait for previous EEPROM writes to complete
- asm volatile(
- "clr r17 \n\t" //page_word_count
- "lds r30,address \n\t" //Address of FLASH location (in bytes)
- "lds r31,address+1 \n\t"
- "ldi r28,lo8(buff) \n\t" //Start of buffer array in RAM
- "ldi r29,hi8(buff) \n\t"
- "lds r24,length \n\t" //Length of data to be written (in bytes)
- "lds r25,length+1 \n\t"
- "length_loop: \n\t" //Main loop, repeat for number of words in block
- "cpi r17,0x00 \n\t" //If page_word_count=0 then erase page
- "brne no_page_erase \n\t"
- "wait_spm1: \n\t"
- "lds r16,%0 \n\t" //Wait for previous spm to complete
- "andi r16,1 \n\t"
- "cpi r16,1 \n\t"
- "breq wait_spm1 \n\t"
- "ldi r16,0x03 \n\t" //Erase page pointed to by Z
- "sts %0,r16 \n\t"
- "spm \n\t"
+ address.word = address.word << 1; //address * 2 -> byte location
+ /* if ((length.byte[0] & 0x01) == 0x01) length.word++; //Even up an odd number of bytes */
+ if ((length.byte[0] & 0x01)) length.word++; //Even up an odd number of bytes
+ cli(); //Disable interrupts, just to be sure
+ // HACKME: EEPE used to be EEWE
+ while(bit_is_set(EECR,EEPE)); //Wait for previous EEPROM writes to complete
+ asm volatile(
+ "clr r17 \n\t" //page_word_count
+ "lds r30,address \n\t" //Address of FLASH location (in bytes)
+ "lds r31,address+1 \n\t"
+ "ldi r28,lo8(buff) \n\t" //Start of buffer array in RAM
+ "ldi r29,hi8(buff) \n\t"
+ "lds r24,length \n\t" //Length of data to be written (in bytes)
+ "lds r25,length+1 \n\t"
+ "length_loop: \n\t" //Main loop, repeat for number of words in block
+ "cpi r17,0x00 \n\t" //If page_word_count=0 then erase page
+ "brne no_page_erase \n\t"
+ "wait_spm1: \n\t"
+ "lds r16,%0 \n\t" //Wait for previous spm to complete
+ "andi r16,1 \n\t"
+ "cpi r16,1 \n\t"
+ "breq wait_spm1 \n\t"
+ "ldi r16,0x03 \n\t" //Erase page pointed to by Z
+ "sts %0,r16 \n\t"
+ "spm \n\t"
#ifdef __AVR_ATmega163__
- ".word 0xFFFF \n\t"
- "nop \n\t"
+ ".word 0xFFFF \n\t"
+ "nop \n\t"
#endif
- "wait_spm2: \n\t"
- "lds r16,%0 \n\t" //Wait for previous spm to complete
- "andi r16,1 \n\t"
- "cpi r16,1 \n\t"
- "breq wait_spm2 \n\t"
-
- "ldi r16,0x11 \n\t" //Re-enable RWW section
- "sts %0,r16 \n\t"
- "spm \n\t"
+ "wait_spm2: \n\t"
+ "lds r16,%0 \n\t" //Wait for previous spm to complete
+ "andi r16,1 \n\t"
+ "cpi r16,1 \n\t"
+ "breq wait_spm2 \n\t"
+
+ "ldi r16,0x11 \n\t" //Re-enable RWW section
+ "sts %0,r16 \n\t"
+ "spm \n\t"
#ifdef __AVR_ATmega163__
- ".word 0xFFFF \n\t"
- "nop \n\t"
+ ".word 0xFFFF \n\t"
+ "nop \n\t"
#endif
- "no_page_erase: \n\t"
- "ld r0,Y+ \n\t" //Write 2 bytes into page buffer
- "ld r1,Y+ \n\t"
-
- "wait_spm3: \n\t"
- "lds r16,%0 \n\t" //Wait for previous spm to complete
- "andi r16,1 \n\t"
- "cpi r16,1 \n\t"
- "breq wait_spm3 \n\t"
- "ldi r16,0x01 \n\t" //Load r0,r1 into FLASH page buffer
- "sts %0,r16 \n\t"
- "spm \n\t"
-
- "inc r17 \n\t" //page_word_count++
- "cpi r17,%1 \n\t"
- "brlo same_page \n\t" //Still same page in FLASH
- "write_page: \n\t"
- "clr r17 \n\t" //New page, write current one first
- "wait_spm4: \n\t"
- "lds r16,%0 \n\t" //Wait for previous spm to complete
- "andi r16,1 \n\t"
- "cpi r16,1 \n\t"
- "breq wait_spm4 \n\t"
+ "no_page_erase: \n\t"
+ "ld r0,Y+ \n\t" //Write 2 bytes into page buffer
+ "ld r1,Y+ \n\t"
+
+ "wait_spm3: \n\t"
+ "lds r16,%0 \n\t" //Wait for previous spm to complete
+ "andi r16,1 \n\t"
+ "cpi r16,1 \n\t"
+ "breq wait_spm3 \n\t"
+ "ldi r16,0x01 \n\t" //Load r0,r1 into FLASH page buffer
+ "sts %0,r16 \n\t"
+ "spm \n\t"
+
+ "inc r17 \n\t" //page_word_count++
+ "cpi r17,%1 \n\t"
+ "brlo same_page \n\t" //Still same page in FLASH
+ "write_page: \n\t"
+ "clr r17 \n\t" //New page, write current one first
+ "wait_spm4: \n\t"
+ "lds r16,%0 \n\t" //Wait for previous spm to complete
+ "andi r16,1 \n\t"
+ "cpi r16,1 \n\t"
+ "breq wait_spm4 \n\t"
#ifdef __AVR_ATmega163__
- "andi r30,0x80 \n\t" // m163 requires Z6:Z1 to be zero during page write
+ "andi r30,0x80 \n\t" // m163 requires Z6:Z1 to be zero during page write
#endif
- "ldi r16,0x05 \n\t" //Write page pointed to by Z
- "sts %0,r16 \n\t"
- "spm \n\t"
+ "ldi r16,0x05 \n\t" //Write page pointed to by Z
+ "sts %0,r16 \n\t"
+ "spm \n\t"
#ifdef __AVR_ATmega163__
- ".word 0xFFFF \n\t"
- "nop \n\t"
- "ori r30,0x7E \n\t" // recover Z6:Z1 state after page write (had to be zero during write)
+ ".word 0xFFFF \n\t"
+ "nop \n\t"
+ "ori r30,0x7E \n\t" // recover Z6:Z1 state after page write (had to be zero during write)
#endif
- "wait_spm5: \n\t"
- "lds r16,%0 \n\t" //Wait for previous spm to complete
- "andi r16,1 \n\t"
- "cpi r16,1 \n\t"
- "breq wait_spm5 \n\t"
- "ldi r16,0x11 \n\t" //Re-enable RWW section
- "sts %0,r16 \n\t"
- "spm \n\t"
+ "wait_spm5: \n\t"
+ "lds r16,%0 \n\t" //Wait for previous spm to complete
+ "andi r16,1 \n\t"
+ "cpi r16,1 \n\t"
+ "breq wait_spm5 \n\t"
+ "ldi r16,0x11 \n\t" //Re-enable RWW section
+ "sts %0,r16 \n\t"
+ "spm \n\t"
#ifdef __AVR_ATmega163__
- ".word 0xFFFF \n\t"
- "nop \n\t"
+ ".word 0xFFFF \n\t"
+ "nop \n\t"
#endif
- "same_page: \n\t"
- "adiw r30,2 \n\t" //Next word in FLASH
- "sbiw r24,2 \n\t" //length-2
- "breq final_write \n\t" //Finished
- "rjmp length_loop \n\t"
- "final_write: \n\t"
- "cpi r17,0 \n\t"
- "breq block_done \n\t"
- "adiw r24,2 \n\t" //length+2, fool above check on length after short page write
- "rjmp write_page \n\t"
- "block_done: \n\t"
- "clr __zero_reg__ \n\t" //restore zero register
+ "same_page: \n\t"
+ "adiw r30,2 \n\t" //Next word in FLASH
+ "sbiw r24,2 \n\t" //length-2
+ "breq final_write \n\t" //Finished
+ "rjmp length_loop \n\t"
+ "final_write: \n\t"
+ "cpi r17,0 \n\t"
+ "breq block_done \n\t"
+ "adiw r24,2 \n\t" //length+2, fool above check on length after short page write
+ "rjmp write_page \n\t"
+ "block_done: \n\t"
+ "clr __zero_reg__ \n\t" //restore zero register
#if defined __AVR_ATmega168__
- : "=m" (SPMCSR) : "M" (PAGE_SIZE) : "r0","r16","r17","r24","r25","r28","r29","r30","r31"
+ : "=m" (SPMCSR) : "M" (PAGE_SIZE) : "r0","r16","r17","r24","r25","r28","r29","r30","r31"
#else
- : "=m" (SPMCR) : "M" (PAGE_SIZE) : "r0","r16","r17","r24","r25","r28","r29","r30","r31"
+ : "=m" (SPMCR) : "M" (PAGE_SIZE) : "r0","r16","r17","r24","r25","r28","r29","r30","r31"
#endif
- );
- /* Should really add a wait for RWW section to be enabled, don't actually need it since we never */
- /* exit the bootloader without a power cycle anyhow */
- }
- putch(0x14);
- putch(0x10);
- } else {
- if (++error_count == MAX_ERROR_COUNT)
- app_start();
- }
+ );
+ /* Should really add a wait for RWW section to be enabled, don't actually need it since we never */
+ /* exit the bootloader without a power cycle anyhow */
+ }
+ putch(0x14);
+ putch(0x10);
+ } else {
+ if (++error_count == MAX_ERROR_COUNT)
+ app_start();
+ }
}
-
- /* Read memory block mode, length is big endian. */
- else if(ch=='t') {
- length.byte[1] = getch();
- length.byte[0] = getch();
+
+ /* Read memory block mode, length is big endian. */
+ else if(ch=='t') {
+ length.byte[1] = getch();
+ length.byte[0] = getch();
#if defined __AVR_ATmega128__
- if (address.word>0x7FFF) flags.rampz = 1; // No go with m256, FIXME
- else flags.rampz = 0;
+ if (address.word>0x7FFF) flags.rampz = 1; // No go with m256, FIXME
+ else flags.rampz = 0;
#endif
- if (getch() == 'E') flags.eeprom = 1;
- else {
- flags.eeprom = 0;
- address.word = address.word << 1; // address * 2 -> byte location
- }
- if (getch() == ' ') { // Command terminator
- putch(0x14);
- for (w=0;w < length.word;w++) { // Can handle odd and even lengths okay
- if (flags.eeprom) { // Byte access EEPROM read
+ if (getch() == 'E') flags.eeprom = 1;
+ else {
+ flags.eeprom = 0;
+ address.word = address.word << 1; // address * 2 -> byte location
+ }
+ if (getch() == ' ') { // Command terminator
+ putch(0x14);
+ for (w=0;w < length.word;w++) { // Can handle odd and even lengths okay
+ if (flags.eeprom) { // Byte access EEPROM read
#ifdef __AVR_ATmega168__
- while(EECR & (1<<EEPE));
- EEAR = (uint16_t)(void *)address.word;
- EECR |= (1<<EERE);
- putch(EEDR);
+ while(EECR & (1<<EEPE));
+ EEAR = (uint16_t)(void *)address.word;
+ EECR |= (1<<EERE);
+ putch(EEDR);
#else
- putch(eeprom_read_byte((void *)address.word));
+ putch(eeprom_read_byte((void *)address.word));
#endif
- address.word++;
- }
- else {
+ address.word++;
+ }
+ else {
- if (!flags.rampz) putch(pgm_read_byte_near(address.word));
+ if (!flags.rampz) putch(pgm_read_byte_near(address.word));
#if defined __AVR_ATmega128__
- else putch(pgm_read_byte_far(address.word + 0x10000));
- // Hmmmm, yuck FIXME when m256 arrvies
+ else putch(pgm_read_byte_far(address.word + 0x10000));
+ // Hmmmm, yuck FIXME when m256 arrvies
#endif
- address.word++;
- }
+ address.word++;
+ }
+ }
+ putch(0x10);
}
- putch(0x10);
- }
}
- /* Get device signature bytes */
- else if(ch=='u') {
- if (getch() == ' ') {
- putch(0x14);
- putch(SIG1);
- putch(SIG2);
- putch(SIG3);
- putch(0x10);
- } else {
- if (++error_count == MAX_ERROR_COUNT)
- app_start();
- }
+ /* Get device signature bytes */
+ else if(ch=='u') {
+ if (getch() == ' ') {
+ putch(0x14);
+ putch(SIG1);
+ putch(SIG2);
+ putch(SIG3);
+ putch(0x10);
+ } else {
+ if (++error_count == MAX_ERROR_COUNT)
+ app_start();
+ }
}
- /* Read oscillator calibration byte */
- else if(ch=='v') {
- byte_response(0x00);
+ /* Read oscillator calibration byte */
+ else if(ch=='v') {
+ byte_response(0x00);
}
@@ -705,179 +705,175 @@ int main(void)
/* check for three times exclamation mark pressed */
else if(ch=='!') {
- ch = getch();
- if(ch=='!') {
+ ch = getch();
+ if(ch=='!') {
ch = getch();
if(ch=='!') {
#ifdef __AVR_ATmega128__
- uint16_t extaddr;
+ uint16_t extaddr;
#endif
- uint8_t addrl, addrh;
+ uint8_t addrl, addrh;
#ifdef CRUMB128
- PGM_P welcome = {"ATmegaBOOT / Crumb128 - (C) J.P.Kyle, E.Lins - 050815\n\r"};
+ PGM_P welcome = {"ATmegaBOOT / Crumb128 - (C) J.P.Kyle, E.Lins - 050815\n\r"};
#elif defined PROBOMEGA128
- PGM_P welcome = {"ATmegaBOOT / PROBOmega128 - (C) J.P.Kyle, E.Lins - 050815\n\r"};
+ PGM_P welcome = {"ATmegaBOOT / PROBOmega128 - (C) J.P.Kyle, E.Lins - 050815\n\r"};
#elif defined SAVVY128
- PGM_P welcome = {"ATmegaBOOT / Savvy128 - (C) J.P.Kyle, E.Lins - 050815\n\r"};
+ PGM_P welcome = {"ATmegaBOOT / Savvy128 - (C) J.P.Kyle, E.Lins - 050815\n\r"};
#endif
- /* turn on LED */
- LED_DDR |= _BV(LED);
- LED_PORT &= ~_BV(LED);
-
- /* print a welcome message and command overview */
- for(i=0; welcome[i] != '\0'; ++i) {
- putch(welcome[i]);
- }
-
- /* test for valid commands */
- for(;;) {
- putch('\n');
- putch('\r');
- putch(':');
- putch(' ');
+ /* turn on LED */
+ LED_DDR |= _BV(LED);
+ LED_PORT &= ~_BV(LED);
- ch = getch();
- putch(ch);
-
- /* toggle LED */
- if(ch == 't') {
- if(bit_is_set(LED_PIN,LED)) {
- LED_PORT &= ~_BV(LED);
- putch('1');
- } else {
- LED_PORT |= _BV(LED);
- putch('0');
- }
-
- }
-
- /* read byte from address */
- else if(ch == 'r') {
- ch = getch(); putch(ch);
- addrh = gethex();
- addrl = gethex();
- putch('=');
- ch = *(uint8_t *)((addrh << 8) + addrl);
- puthex(ch);
+ /* print a welcome message and command overview */
+ for(i=0; welcome[i] != '\0'; ++i) {
+ putch(welcome[i]);
}
- /* write a byte to address */
- else if(ch == 'w') {
- ch = getch(); putch(ch);
- addrh = gethex();
- addrl = gethex();
- ch = getch(); putch(ch);
- ch = gethex();
- *(uint8_t *)((addrh << 8) + addrl) = ch;
+ /* test for valid commands */
+ for(;;) {
+ putch('\n');
+ putch('\r');
+ putch(':');
+ putch(' ');
+
+ ch = getch();
+ putch(ch);
+
+ /* toggle LED */
+ if(ch == 't') {
+ if(bit_is_set(LED_PIN,LED)) {
+ LED_PORT &= ~_BV(LED);
+ putch('1');
+ } else {
+ LED_PORT |= _BV(LED);
+ putch('0');
+ }
+ }
+
+ /* read byte from address */
+ else if(ch == 'r') {
+ ch = getch(); putch(ch);
+ addrh = gethex();
+ addrl = gethex();
+ putch('=');
+ ch = *(uint8_t *)((addrh << 8) + addrl);
+ puthex(ch);
+ }
- }
+ /* write a byte to address */
+ else if(ch == 'w') {
+ ch = getch(); putch(ch);
+ addrh = gethex();
+ addrl = gethex();
+ ch = getch(); putch(ch);
+ ch = gethex();
+ *(uint8_t *)((addrh << 8) + addrl) = ch;
+ }
- /* read from uart and echo back */
- else if(ch == 'u') {
- for(;;) {
- putch(getch());
- }
- }
+ /* read from uart and echo back */
+ else if(ch == 'u') {
+ for(;;) {
+ putch(getch());
+ }
+ }
#ifdef __AVR_ATmega128__
- /* external bus loop */
- else if(ch == 'b') {
- putch('b');
- putch('u');
- putch('s');
- MCUCR = 0x80;
- XMCRA = 0;
- XMCRB = 0;
- extaddr = 0x1100;
- for(;;) {
- ch = *(volatile uint8_t *)extaddr;
- if(++extaddr == 0) {
- extaddr = 0x1100;
+ /* external bus loop */
+ else if(ch == 'b') {
+ putch('b');
+ putch('u');
+ putch('s');
+ MCUCR = 0x80;
+ XMCRA = 0;
+ XMCRB = 0;
+ extaddr = 0x1100;
+ for(;;) {
+ ch = *(volatile uint8_t *)extaddr;
+ if(++extaddr == 0) {
+ extaddr = 0x1100;
+ }
+ }
}
- }
- }
#endif
- else if(ch == 'j') {
- app_start();
- }
+ else if(ch == 'j') {
+ app_start();
+ }
- }
- /* end of monitor functions */
+ } /* end of monitor functions */
}
- }
+ }
}
/* end of monitor */
#endif
else if (++error_count == MAX_ERROR_COUNT) {
- app_start();
+ app_start();
}
- }
- /* end of forever loop */
+ } /* end of forever loop */
}
char gethex(void) {
- char ah,al;
-
- ah = getch(); putch(ah);
- al = getch(); putch(al);
- if(ah >= 'a') {
- ah = ah - 'a' + 0x0a;
- } else if(ah >= '0') {
- ah -= '0';
- }
- if(al >= 'a') {
- al = al - 'a' + 0x0a;
- } else if(al >= '0') {
- al -= '0';
- }
- return (ah << 4) + al;
+ char ah,al;
+
+ ah = getch(); putch(ah);
+ al = getch(); putch(al);
+ if(ah >= 'a') {
+ ah = ah - 'a' + 0x0a;
+ } else if(ah >= '0') {
+ ah -= '0';
+ }
+ if(al >= 'a') {
+ al = al - 'a' + 0x0a;
+ } else if(al >= '0') {
+ al -= '0';
+ }
+ return (ah << 4) + al;
}
void puthex(char ch) {
- char ah,al;
-
- ah = (ch & 0xf0) >> 4;
- if(ah >= 0x0a) {
- ah = ah - 0x0a + 'a';
- } else {
- ah += '0';
- }
- al = (ch & 0x0f);
- if(al >= 0x0a) {
- al = al - 0x0a + 'a';
- } else {
- al += '0';
- }
- putch(ah);
- putch(al);
+ char ah,al;
+
+ ah = (ch & 0xf0) >> 4;
+ if(ah >= 0x0a) {
+ ah = ah - 0x0a + 'a';
+ } else {
+ ah += '0';
+ }
+ al = (ch & 0x0f);
+ if(al >= 0x0a) {
+ al = al - 0x0a + 'a';
+ } else {
+ al += '0';
+ }
+ putch(ah);
+ putch(al);
}
void putch(char ch)
{
#ifdef __AVR_ATmega128__
- if(bootuart == 1) {
+ if(bootuart == 1) {
+ while (!(UCSR0A & _BV(UDRE0)));
+ UDR0 = ch;
+ }
+ else if (bootuart == 2) {
+ while (!(UCSR1A & _BV(UDRE1)));
+ UDR1 = ch;
+ }
+#elif defined __AVR_ATmega168__
while (!(UCSR0A & _BV(UDRE0)));
UDR0 = ch;
- }
- else if (bootuart == 2) {
- while (!(UCSR1A & _BV(UDRE1)));
- UDR1 = ch;
- }
-#elif defined __AVR_ATmega168__
- while (!(UCSR0A & _BV(UDRE0)));
- UDR0 = ch;
#else
- /* m8,16,32,169,8515,8535,163 */
- while (!(UCSRA & _BV(UDRE)));
- UDR = ch;
+ /* m8,16,32,169,8515,8535,163 */
+ while (!(UCSRA & _BV(UDRE)));
+ UDR = ch;
#endif
}
@@ -885,111 +881,111 @@ void putch(char ch)
char getch(void)
{
#ifdef __AVR_ATmega128__
- if(bootuart == 1) {
- while(!(UCSR0A & _BV(RXC0)));
- return UDR0;
- }
- else if(bootuart == 2) {
- while(!(UCSR1A & _BV(RXC1)));
- return UDR1;
- }
- return 0;
+ if(bootuart == 1) {
+ while(!(UCSR0A & _BV(RXC0)));
+ return UDR0;
+ }
+ else if(bootuart == 2) {
+ while(!(UCSR1A & _BV(RXC1)));
+ return UDR1;
+ }
+ return 0;
#elif defined __AVR_ATmega168__
- uint32_t count = 0;
- while(!(UCSR0A & _BV(RXC0))){
- /* 20060803 DojoCorp:: Addon coming from the previous Bootloader*/
- /* HACKME:: here is a good place to count times*/
- count++;
- if (count > MAX_TIME_COUNT)
- app_start();
- }
- return UDR0;
+ uint32_t count = 0;
+ while(!(UCSR0A & _BV(RXC0))){
+ /* 20060803 DojoCorp:: Addon coming from the previous Bootloader*/
+ /* HACKME:: here is a good place to count times*/
+ count++;
+ if (count > MAX_TIME_COUNT)
+ app_start();
+ }
+ return UDR0;
#else
- /* m8,16,32,169,8515,8535,163 */
- uint32_t count = 0;
- while(!(UCSRA & _BV(RXC))){
- /* 20060803 DojoCorp:: Addon coming from the previous Bootloader*/
- /* HACKME:: here is a good place to count times*/
- count++;
- if (count > MAX_TIME_COUNT)
- app_start();
- }
- return UDR;
+ /* m8,16,32,169,8515,8535,163 */
+ uint32_t count = 0;
+ while(!(UCSRA & _BV(RXC))){
+ /* 20060803 DojoCorp:: Addon coming from the previous Bootloader*/
+ /* HACKME:: here is a good place to count times*/
+ count++;
+ if (count > MAX_TIME_COUNT)
+ app_start();
+ }
+ return UDR;
#endif
}
void getNch(uint8_t count)
{
- uint8_t i;
- for(i=0;i<count;i++) {
+ uint8_t i;
+ for(i=0;i<count;i++) {
#ifdef __AVR_ATmega128__
- if(bootuart == 1) {
- while(!(UCSR0A & _BV(RXC0)));
- UDR0;
- }
- else if(bootuart == 2) {
- while(!(UCSR1A & _BV(RXC1)));
- UDR1;
- }
+ if(bootuart == 1) {
+ while(!(UCSR0A & _BV(RXC0)));
+ UDR0;
+ }
+ else if(bootuart == 2) {
+ while(!(UCSR1A & _BV(RXC1)));
+ UDR1;
+ }
#elif defined __AVR_ATmega168__
- while(!(UCSR0A & _BV(RXC0)));
- UDR0;
+ while(!(UCSR0A & _BV(RXC0)));
+ UDR0;
#else
- /* m8,16,32,169,8515,8535,163 */
- /* 20060803 DojoCorp:: Addon coming from the previous Bootloader*/
- //while(!(UCSRA & _BV(RXC)));
- //UDR;
- uint8_t i;
- for(i=0;i<count;i++) {
- getch(); // need to handle time out
- }
+ /* m8,16,32,169,8515,8535,163 */
+ /* 20060803 DojoCorp:: Addon coming from the previous Bootloader*/
+ //while(!(UCSRA & _BV(RXC)));
+ //UDR;
+ uint8_t i;
+ for(i=0;i<count;i++) {
+ getch(); // need to handle time out
+ }
#endif
- }
+ }
}
void byte_response(uint8_t val)
{
- if (getch() == ' ') {
- putch(0x14);
- putch(val);
- putch(0x10);
- } else {
- if (++error_count == MAX_ERROR_COUNT)
- app_start();
- }
+ if (getch() == ' ') {
+ putch(0x14);
+ putch(val);
+ putch(0x10);
+ } else {
+ if (++error_count == MAX_ERROR_COUNT)
+ app_start();
+ }
}
void nothing_response(void)
{
- if (getch() == ' ') {
- putch(0x14);
- putch(0x10);
- } else {
- if (++error_count == MAX_ERROR_COUNT)
- app_start();
- }
+ if (getch() == ' ') {
+ putch(0x14);
+ putch(0x10);
+ } else {
+ if (++error_count == MAX_ERROR_COUNT)
+ app_start();
+ }
}
void flash_led(uint8_t count)
{
- /* flash onboard LED three times to signal entering of bootloader */
+ /* flash onboard LED three times to signal entering of bootloader */
/* l needs to be volatile or the delay loops below might get
optimized away if compiling with optimizations (DAM). */
- volatile uint32_t l;
-
- if (count == 0) {
- count = 3;
- }
-
- for (i = 0; i < count; ++i) {
- LED_PORT |= _BV(LED);
- for(l = 0; l < (F_CPU / 1000); ++l);
- LED_PORT &= ~_BV(LED);
- for(l = 0; l < (F_CPU / 1000); ++l);
- }
+ volatile uint32_t l;
+
+ if (count == 0) {
+ count = 3;
+ }
+
+ for (i = 0; i < count; ++i) {
+ LED_PORT |= _BV(LED);
+ for(l = 0; l < (F_CPU / 1000); ++l);
+ LED_PORT &= ~_BV(LED);
+ for(l = 0; l < (F_CPU / 1000); ++l);
+ }
}