: #ifdef VIRTUAL_BOOT_PARTITION #define rstVect (*(uint16_t*)(0x204)) #define wdtVect (*(uint16_t*)(0x206)) #endif /* main program starts here */ int main(void) { 7e00: 85 e0 ldi r24, 0x05 ; 5 7e02: 80 93 81 00 sts 0x0081, r24 #if LED_START_FLASHES > 0 // Set up Timer 1 for timeout counter TCCR1B = _BV(CS12) | _BV(CS10); // div 1024 #endif #ifndef SOFT_UART UCSR0A = _BV(U2X0); //Double speed mode USART0 7e06: 82 e0 ldi r24, 0x02 ; 2 7e08: 80 93 c0 00 sts 0x00C0, r24 UCSR0B = _BV(RXEN0) | _BV(TXEN0); 7e0c: 88 e1 ldi r24, 0x18 ; 24 7e0e: 80 93 c1 00 sts 0x00C1, r24 UCSR0C = _BV(UCSZ00) | _BV(UCSZ01); 7e12: 86 e0 ldi r24, 0x06 ; 6 7e14: 80 93 c2 00 sts 0x00C2, r24 UBRR0L = (uint8_t)( (F_CPU + BAUD_RATE * 4L) / (BAUD_RATE * 8L) - 1 ); 7e18: 88 e0 ldi r24, 0x08 ; 8 7e1a: 80 93 c4 00 sts 0x00C4, r24 #endif // Adaboot no-wait mod ch = MCUSR; 7e1e: 84 b7 in r24, 0x34 ; 52 MCUSR = 0; 7e20: 14 be out 0x34, r1 ; 52 if (!(ch & _BV(EXTRF))) appStart(); 7e22: 81 ff sbrs r24, 1 7e24: d0 d0 rcall .+416 ; 0x7fc6 // Set up watchdog to trigger after 500ms watchdogConfig(WATCHDOG_500MS); 7e26: 8d e0 ldi r24, 0x0D ; 13 7e28: c8 d0 rcall .+400 ; 0x7fba /* Set LED pin as output */ LED_DDR |= _BV(LED); 7e2a: 25 9a sbi 0x04, 5 ; 4 7e2c: 86 e0 ldi r24, 0x06 ; 6 } #if LED_START_FLASHES > 0 void flash_led(uint8_t count) { do { TCNT1 = -(F_CPU/(1024*16)); 7e2e: 28 e1 ldi r18, 0x18 ; 24 7e30: 3e ef ldi r19, 0xFE ; 254 TIFR1 = _BV(TOV1); 7e32: 91 e0 ldi r25, 0x01 ; 1 } #if LED_START_FLASHES > 0 void flash_led(uint8_t count) { do { TCNT1 = -(F_CPU/(1024*16)); 7e34: 30 93 85 00 sts 0x0085, r19 7e38: 20 93 84 00 sts 0x0084, r18 TIFR1 = _BV(TOV1); 7e3c: 96 bb out 0x16, r25 ; 22 while(!(TIFR1 & _BV(TOV1))); 7e3e: b0 9b sbis 0x16, 0 ; 22 7e40: fe cf rjmp .-4 ; 0x7e3e LED_PIN |= _BV(LED); 7e42: 1d 9a sbi 0x03, 5 ; 3 return getch(); } // Watchdog functions. These are only safe with interrupts turned off. void watchdogReset() { __asm__ __volatile__ ( 7e44: a8 95 wdr TCNT1 = -(F_CPU/(1024*16)); TIFR1 = _BV(TOV1); while(!(TIFR1 & _BV(TOV1))); LED_PIN |= _BV(LED); watchdogReset(); } while (--count); 7e46: 81 50 subi r24, 0x01 ; 1 7e48: a9 f7 brne .-22 ; 0x7e34 /* get character from UART */ ch = getch(); if(ch == STK_GET_PARAMETER) { // GET PARAMETER returns a generic 0x03 reply - enough to keep Avrdude happy getNch(1); 7e4a: dd 24 eor r13, r13 7e4c: d3 94 inc r13 boot_page_fill((uint16_t)(void*)addrPtr,a); addrPtr += 2; } while (--ch); // Write from programming buffer boot_page_write((uint16_t)(void*)address); 7e4e: a5 e0 ldi r26, 0x05 ; 5 7e50: ea 2e mov r14, r26 boot_spm_busy_wait(); #if defined(RWWSRE) // Reenable read access to flash boot_rww_enable(); 7e52: f1 e1 ldi r31, 0x11 ; 17 7e54: ff 2e mov r15, r31 #endif /* Forever loop */ for (;;) { /* get character from UART */ ch = getch(); 7e56: a4 d0 rcall .+328 ; 0x7fa0 if(ch == STK_GET_PARAMETER) { 7e58: 81 34 cpi r24, 0x41 ; 65 7e5a: 21 f4 brne .+8 ; 0x7e64 // GET PARAMETER returns a generic 0x03 reply - enough to keep Avrdude happy getNch(1); 7e5c: 81 e0 ldi r24, 0x01 ; 1 7e5e: be d0 rcall .+380 ; 0x7fdc putch(0x03); 7e60: 83 e0 ldi r24, 0x03 ; 3 7e62: 24 c0 rjmp .+72 ; 0x7eac } else if(ch == STK_SET_DEVICE) { 7e64: 82 34 cpi r24, 0x42 ; 66 7e66: 11 f4 brne .+4 ; 0x7e6c // SET DEVICE is ignored getNch(20); 7e68: 84 e1 ldi r24, 0x14 ; 20 7e6a: 03 c0 rjmp .+6 ; 0x7e72 } else if(ch == STK_SET_DEVICE_EXT) { 7e6c: 85 34 cpi r24, 0x45 ; 69 7e6e: 19 f4 brne .+6 ; 0x7e76 // SET DEVICE EXT is ignored getNch(5); 7e70: 85 e0 ldi r24, 0x05 ; 5 7e72: b4 d0 rcall .+360 ; 0x7fdc 7e74: 8a c0 rjmp .+276 ; 0x7f8a } else if(ch == STK_LOAD_ADDRESS) { 7e76: 85 35 cpi r24, 0x55 ; 85 7e78: a1 f4 brne .+40 ; 0x7ea2 // LOAD ADDRESS address = getch(); 7e7a: 92 d0 rcall .+292 ; 0x7fa0 7e7c: 08 2f mov r16, r24 7e7e: 10 e0 ldi r17, 0x00 ; 0 7e80: 10 93 01 02 sts 0x0201, r17 7e84: 00 93 00 02 sts 0x0200, r16 address = (address & 0xff) | (getch() << 8); 7e88: 8b d0 rcall .+278 ; 0x7fa0 7e8a: 90 e0 ldi r25, 0x00 ; 0 7e8c: 98 2f mov r25, r24 7e8e: 88 27 eor r24, r24 7e90: 80 2b or r24, r16 7e92: 91 2b or r25, r17 address += address; // Convert from word address to byte address 7e94: 88 0f add r24, r24 7e96: 99 1f adc r25, r25 7e98: 90 93 01 02 sts 0x0201, r25 7e9c: 80 93 00 02 sts 0x0200, r24 7ea0: 73 c0 rjmp .+230 ; 0x7f88 verifySpace(); } else if(ch == STK_UNIVERSAL) { 7ea2: 86 35 cpi r24, 0x56 ; 86 7ea4: 29 f4 brne .+10 ; 0x7eb0 // UNIVERSAL command is ignored getNch(4); 7ea6: 84 e0 ldi r24, 0x04 ; 4 7ea8: 99 d0 rcall .+306 ; 0x7fdc putch(0x00); 7eaa: 80 e0 ldi r24, 0x00 ; 0 7eac: 71 d0 rcall .+226 ; 0x7f90 7eae: 6d c0 rjmp .+218 ; 0x7f8a } /* Write memory, length is big endian and is in bytes */ else if(ch == STK_PROG_PAGE) { 7eb0: 84 36 cpi r24, 0x64 ; 100 7eb2: 09 f0 breq .+2 ; 0x7eb6 7eb4: 43 c0 rjmp .+134 ; 0x7f3c // PROGRAM PAGE - we support flash programming only, not EEPROM uint8_t *bufPtr; uint16_t addrPtr; getLen(); 7eb6: 7c d0 rcall .+248 ; 0x7fb0 // Immediately start page erase - this will 4.5ms boot_page_erase((uint16_t)(void*)address); 7eb8: e0 91 00 02 lds r30, 0x0200 7ebc: f0 91 01 02 lds r31, 0x0201 7ec0: 83 e0 ldi r24, 0x03 ; 3 7ec2: 80 93 57 00 sts 0x0057, r24 7ec6: e8 95 spm 7ec8: c0 e0 ldi r28, 0x00 ; 0 7eca: d1 e0 ldi r29, 0x01 ; 1 // While that is going on, read in page contents bufPtr = buff; do *bufPtr++ = getch(); 7ecc: 69 d0 rcall .+210 ; 0x7fa0 7ece: 89 93 st Y+, r24 while (--length); 7ed0: 80 91 02 02 lds r24, 0x0202 7ed4: 81 50 subi r24, 0x01 ; 1 7ed6: 80 93 02 02 sts 0x0202, r24 7eda: 88 23 and r24, r24 7edc: b9 f7 brne .-18 ; 0x7ecc // Read command terminator, start reply verifySpace(); 7ede: 78 d0 rcall .+240 ; 0x7fd0 // If only a partial page is to be programmed, the erase might not be complete. // So check that here boot_spm_busy_wait(); 7ee0: 07 b6 in r0, 0x37 ; 55 7ee2: 00 fc sbrc r0, 0 7ee4: fd cf rjmp .-6 ; 0x7ee0 } #endif // Copy buffer into programming buffer bufPtr = buff; addrPtr = (uint16_t)(void*)address; 7ee6: 40 91 00 02 lds r20, 0x0200 7eea: 50 91 01 02 lds r21, 0x0201 7eee: a0 e0 ldi r26, 0x00 ; 0 7ef0: b1 e0 ldi r27, 0x01 ; 1 ch = SPM_PAGESIZE / 2; do { uint16_t a; a = *bufPtr++; 7ef2: 2c 91 ld r18, X 7ef4: 30 e0 ldi r19, 0x00 ; 0 a |= (*bufPtr++) << 8; 7ef6: 11 96 adiw r26, 0x01 ; 1 7ef8: 8c 91 ld r24, X 7efa: 11 97 sbiw r26, 0x01 ; 1 7efc: 90 e0 ldi r25, 0x00 ; 0 7efe: 98 2f mov r25, r24 7f00: 88 27 eor r24, r24 7f02: 82 2b or r24, r18 7f04: 93 2b or r25, r19 #ifdef VIRTUAL_BOOT_PARTITION #define rstVect (*(uint16_t*)(0x204)) #define wdtVect (*(uint16_t*)(0x206)) #endif /* main program starts here */ int main(void) { 7f06: 12 96 adiw r26, 0x02 ; 2 ch = SPM_PAGESIZE / 2; do { uint16_t a; a = *bufPtr++; a |= (*bufPtr++) << 8; boot_page_fill((uint16_t)(void*)addrPtr,a); 7f08: fa 01 movw r30, r20 7f0a: 0c 01 movw r0, r24 7f0c: d0 92 57 00 sts 0x0057, r13 7f10: e8 95 spm 7f12: 11 24 eor r1, r1 addrPtr += 2; 7f14: 4e 5f subi r20, 0xFE ; 254 7f16: 5f 4f sbci r21, 0xFF ; 255 } while (--ch); 7f18: f1 e0 ldi r31, 0x01 ; 1 7f1a: a0 38 cpi r26, 0x80 ; 128 7f1c: bf 07 cpc r27, r31 7f1e: 49 f7 brne .-46 ; 0x7ef2 // Write from programming buffer boot_page_write((uint16_t)(void*)address); 7f20: e0 91 00 02 lds r30, 0x0200 7f24: f0 91 01 02 lds r31, 0x0201 7f28: e0 92 57 00 sts 0x0057, r14 7f2c: e8 95 spm boot_spm_busy_wait(); 7f2e: 07 b6 in r0, 0x37 ; 55 7f30: 00 fc sbrc r0, 0 7f32: fd cf rjmp .-6 ; 0x7f2e #if defined(RWWSRE) // Reenable read access to flash boot_rww_enable(); 7f34: f0 92 57 00 sts 0x0057, r15 7f38: e8 95 spm 7f3a: 27 c0 rjmp .+78 ; 0x7f8a #endif } /* Read memory block mode, length is big endian. */ else if(ch == STK_READ_PAGE) { 7f3c: 84 37 cpi r24, 0x74 ; 116 7f3e: b9 f4 brne .+46 ; 0x7f6e // READ PAGE - we only read flash getLen(); 7f40: 37 d0 rcall .+110 ; 0x7fb0 verifySpace(); 7f42: 46 d0 rcall .+140 ; 0x7fd0 else ch = pgm_read_byte_near(address); address++; putch(ch); } while (--length); #else do putch(pgm_read_byte_near(address++)); 7f44: e0 91 00 02 lds r30, 0x0200 7f48: f0 91 01 02 lds r31, 0x0201 7f4c: 31 96 adiw r30, 0x01 ; 1 7f4e: f0 93 01 02 sts 0x0201, r31 7f52: e0 93 00 02 sts 0x0200, r30 7f56: 31 97 sbiw r30, 0x01 ; 1 7f58: e4 91 lpm r30, Z+ 7f5a: 8e 2f mov r24, r30 7f5c: 19 d0 rcall .+50 ; 0x7f90 while (--length); 7f5e: 80 91 02 02 lds r24, 0x0202 7f62: 81 50 subi r24, 0x01 ; 1 7f64: 80 93 02 02 sts 0x0202, r24 7f68: 88 23 and r24, r24 7f6a: 61 f7 brne .-40 ; 0x7f44 7f6c: 0e c0 rjmp .+28 ; 0x7f8a #endif } /* Get device signature bytes */ else if(ch == STK_READ_SIGN) { 7f6e: 85 37 cpi r24, 0x75 ; 117 7f70: 39 f4 brne .+14 ; 0x7f80 // READ SIGN - return what Avrdude wants to hear verifySpace(); 7f72: 2e d0 rcall .+92 ; 0x7fd0 putch(SIGNATURE_0); 7f74: 8e e1 ldi r24, 0x1E ; 30 7f76: 0c d0 rcall .+24 ; 0x7f90 putch(SIGNATURE_1); 7f78: 85 e9 ldi r24, 0x95 ; 149 7f7a: 0a d0 rcall .+20 ; 0x7f90 putch(SIGNATURE_2); 7f7c: 8f e0 ldi r24, 0x0F ; 15 7f7e: 96 cf rjmp .-212 ; 0x7eac } else if (ch == 'Q') { 7f80: 81 35 cpi r24, 0x51 ; 81 7f82: 11 f4 brne .+4 ; 0x7f88 // Adaboot no-wait mod watchdogConfig(WATCHDOG_16MS); 7f84: 88 e0 ldi r24, 0x08 ; 8 7f86: 19 d0 rcall .+50 ; 0x7fba verifySpace(); } else { // This covers the response to commands like STK_ENTER_PROGMODE verifySpace(); 7f88: 23 d0 rcall .+70 ; 0x7fd0 } putch(STK_OK); 7f8a: 80 e1 ldi r24, 0x10 ; 16 7f8c: 01 d0 rcall .+2 ; 0x7f90 7f8e: 63 cf rjmp .-314 ; 0x7e56 00007f90 : } } void putch(char ch) { 7f90: 98 2f mov r25, r24 #ifndef SOFT_UART while (!(UCSR0A & _BV(UDRE0))); 7f92: 80 91 c0 00 lds r24, 0x00C0 7f96: 85 ff sbrs r24, 5 7f98: fc cf rjmp .-8 ; 0x7f92 UDR0 = ch; 7f9a: 90 93 c6 00 sts 0x00C6, r25 [uartBit] "I" (UART_TX_BIT) : "r25" ); #endif } 7f9e: 08 95 ret 00007fa0 : return getch(); } // Watchdog functions. These are only safe with interrupts turned off. void watchdogReset() { __asm__ __volatile__ ( 7fa0: a8 95 wdr [uartBit] "I" (UART_RX_BIT) : "r25" ); #else while(!(UCSR0A & _BV(RXC0))); 7fa2: 80 91 c0 00 lds r24, 0x00C0 7fa6: 87 ff sbrs r24, 7 7fa8: fc cf rjmp .-8 ; 0x7fa2 ch = UDR0; 7faa: 80 91 c6 00 lds r24, 0x00C6 #ifdef LED_DATA_FLASH LED_PIN |= _BV(LED); #endif return ch; } 7fae: 08 95 ret 00007fb0 : } while (--count); } #endif uint8_t getLen() { getch(); 7fb0: f7 df rcall .-18 ; 0x7fa0 length = getch(); 7fb2: f6 df rcall .-20 ; 0x7fa0 7fb4: 80 93 02 02 sts 0x0202, r24 return getch(); } 7fb8: f3 cf rjmp .-26 ; 0x7fa0 00007fba : "wdr\n" ); } void watchdogConfig(uint8_t x) { WDTCSR = _BV(WDCE) | _BV(WDE); 7fba: e0 e6 ldi r30, 0x60 ; 96 7fbc: f0 e0 ldi r31, 0x00 ; 0 7fbe: 98 e1 ldi r25, 0x18 ; 24 7fc0: 90 83 st Z, r25 WDTCSR = x; 7fc2: 80 83 st Z, r24 } 7fc4: 08 95 ret 00007fc6 : void appStart() { watchdogConfig(WATCHDOG_OFF); 7fc6: 80 e0 ldi r24, 0x00 ; 0 7fc8: f8 df rcall .-16 ; 0x7fba __asm__ __volatile__ ( 7fca: ee 27 eor r30, r30 7fcc: ff 27 eor r31, r31 7fce: 09 94 ijmp 00007fd0 : do getch(); while (--count); verifySpace(); } void verifySpace() { if (getch() != CRC_EOP) appStart(); 7fd0: e7 df rcall .-50 ; 0x7fa0 7fd2: 80 32 cpi r24, 0x20 ; 32 7fd4: 09 f0 breq .+2 ; 0x7fd8 7fd6: f7 df rcall .-18 ; 0x7fc6 putch(STK_INSYNC); 7fd8: 84 e1 ldi r24, 0x14 ; 20 } 7fda: da cf rjmp .-76 ; 0x7f90 ::[count] "M" (UART_B_VALUE) ); } #endif void getNch(uint8_t count) { 7fdc: 1f 93 push r17 7fde: 18 2f mov r17, r24 00007fe0 : do getch(); while (--count); 7fe0: df df rcall .-66 ; 0x7fa0 7fe2: 11 50 subi r17, 0x01 ; 1 7fe4: e9 f7 brne .-6 ; 0x7fe0 verifySpace(); 7fe6: f4 df rcall .-24 ; 0x7fd0 } 7fe8: 1f 91 pop r17 7fea: 08 95 ret