path: root/bootloaders/optiboot/optiboot_luminet.lst

optiboot_luminet.elf:     file format elf32-avr

Sections:
Idx Name          Size      VMA       LMA       File off  Algn
  0 .version      00000002  00001efe  00001efe  000002c8  2**0
                  CONTENTS, READONLY
  1 .text         00000274  00000000  00000000  00000054  2**1
                  CONTENTS, ALLOC, LOAD, READONLY, CODE
  2 .debug_aranges 00000028  00000000  00000000  000002ca  2**0
                  CONTENTS, READONLY, DEBUGGING
  3 .debug_pubnames 00000078  00000000  00000000  000002f2  2**0
                  CONTENTS, READONLY, DEBUGGING
  4 .debug_info   000002a5  00000000  00000000  0000036a  2**0
                  CONTENTS, READONLY, DEBUGGING
  5 .debug_abbrev 0000019d  00000000  00000000  0000060f  2**0
                  CONTENTS, READONLY, DEBUGGING
  6 .debug_line   000004ac  00000000  00000000  000007ac  2**0
                  CONTENTS, READONLY, DEBUGGING
  7 .debug_frame  000000a0  00000000  00000000  00000c58  2**2
                  CONTENTS, READONLY, DEBUGGING
  8 .debug_str    00000150  00000000  00000000  00000cf8  2**0
                  CONTENTS, READONLY, DEBUGGING
  9 .debug_loc    00000194  00000000  00000000  00000e48  2**0
                  CONTENTS, READONLY, DEBUGGING
 10 .debug_ranges 00000088  00000000  00000000  00000fdc  2**0
                  CONTENTS, READONLY, DEBUGGING

Disassembly of section .text:

00000000 <main>:
#define rstVect (*(uint16_t*)(RAMSTART+SPM_PAGESIZE*2+4))
#define wdtVect (*(uint16_t*)(RAMSTART+SPM_PAGESIZE*2+6))
#endif

/* main program starts here */
int main(void) {
   0:	11 24       	eor	r1, r1
#ifdef __AVR_ATmega8__
  SP=RAMEND;  // This is done by hardware reset
#endif

  // Adaboot no-wait mod
  ch = MCUSR;
   2:	84 b7       	in	r24, 0x34	; 52
  MCUSR = 0;
   4:	14 be       	out	0x34, r1	; 52
  if (!(ch & _BV(EXTRF))) appStart();
   6:	81 ff       	sbrs	r24, 1
   8:	22 d1       	rcall	.+580    	; 0x24e <appStart>

#if LED_START_FLASHES > 0
  // Set up Timer 1 for timeout counter
  TCCR1B = _BV(CS12) | _BV(CS10); // div 1024
   a:	85 e0       	ldi	r24, 0x05	; 5
   c:	8e bd       	out	0x2e, r24	; 46
  UBRR0L = (uint8_t)( (F_CPU + BAUD_RATE * 4L) / (BAUD_RATE * 8L) - 1 );
#endif
#endif

  // Set up watchdog to trigger after 500ms
  watchdogConfig(WATCHDOG_1S);
   e:	8e e0       	ldi	r24, 0x0E	; 14
  10:	1a d1       	rcall	.+564    	; 0x246 <watchdogConfig>

  /* Set LED pin as output */
  LED_DDR |= _BV(LED);
  12:	d4 9a       	sbi	0x1a, 4	; 26

#ifdef SOFT_UART
  /* Set TX pin as output */
  UART_DDR |= _BV(UART_TX_BIT);
  14:	d2 9a       	sbi	0x1a, 2	; 26
  16:	86 e0       	ldi	r24, 0x06	; 6
}

#if LED_START_FLASHES > 0
void flash_led(uint8_t count) {
  do {
    TCNT1 = -(F_CPU/(1024*16));
  18:	23 ec       	ldi	r18, 0xC3	; 195
  1a:	3f ef       	ldi	r19, 0xFF	; 255
    TIFR1 = _BV(TOV1);
  1c:	91 e0       	ldi	r25, 0x01	; 1
}

#if LED_START_FLASHES > 0
void flash_led(uint8_t count) {
  do {
    TCNT1 = -(F_CPU/(1024*16));
  1e:	3d bd       	out	0x2d, r19	; 45
  20:	2c bd       	out	0x2c, r18	; 44
    TIFR1 = _BV(TOV1);
  22:	9b b9       	out	0x0b, r25	; 11
    while(!(TIFR1 & _BV(TOV1)));
  24:	58 9b       	sbis	0x0b, 0	; 11
  26:	fe cf       	rjmp	.-4      	; 0x24 <__zero_reg__+0x23>
#ifdef __AVR_ATmega8__
    LED_PORT ^= _BV(LED);
#else
    LED_PIN |= _BV(LED);
  28:	cc 9a       	sbi	0x19, 4	; 25
  return getch();
}

// Watchdog functions. These are only safe with interrupts turned off.
void watchdogReset() {
  __asm__ __volatile__ (
  2a:	a8 95       	wdr
    LED_PORT ^= _BV(LED);
#else
    LED_PIN |= _BV(LED);
#endif
    watchdogReset();
  } while (--count);
  2c:	81 50       	subi	r24, 0x01	; 1
  2e:	b9 f7       	brne	.-18     	; 0x1e <__zero_reg__+0x1d>
    /* 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);
  30:	dd 24       	eor	r13, r13
  32:	d3 94       	inc	r13
        __boot_page_fill_short((uint16_t)(void*)addrPtr,a);
        addrPtr += 2;
      } while (--ch);

      // Write from programming buffer
      __boot_page_write_short((uint16_t)(void*)address);
  34:	85 e0       	ldi	r24, 0x05	; 5
  36:	c8 2e       	mov	r12, r24
        vect -= 4; // Instruction is a relative jump (rjmp), so recalculate.
        buff[8] = vect & 0xff;
        buff[9] = vect >> 8;

        // Add jump to bootloader at RESET vector
        buff[0] = 0x7f;
  38:	0f e7       	ldi	r16, 0x7F	; 127
  3a:	f0 2e       	mov	r15, r16
        buff[1] = 0xce; // rjmp 0x1d00 instruction
  3c:	1e ec       	ldi	r17, 0xCE	; 206
  3e:	e1 2e       	mov	r14, r17
#endif

  /* Forever loop */
  for (;;) {
    /* get character from UART */
    ch = getch();
  40:	e9 d0       	rcall	.+466    	; 0x214 <getch>

    if(ch == STK_GET_PARAMETER) {
  42:	81 34       	cpi	r24, 0x41	; 65
  44:	21 f4       	brne	.+8      	; 0x4e <__SREG__+0xf>
      // GET PARAMETER returns a generic 0x03 reply - enough to keep Avrdude happy
      getNch(1);
  46:	81 e0       	ldi	r24, 0x01	; 1
  48:	0d d1       	rcall	.+538    	; 0x264 <getNch>
      putch(0x03);
  4a:	83 e0       	ldi	r24, 0x03	; 3
  4c:	20 c0       	rjmp	.+64     	; 0x8e <__SREG__+0x4f>
    }
    else if(ch == STK_SET_DEVICE) {
  4e:	82 34       	cpi	r24, 0x42	; 66
  50:	11 f4       	brne	.+4      	; 0x56 <__SREG__+0x17>
      // SET DEVICE is ignored
      getNch(20);
  52:	84 e1       	ldi	r24, 0x14	; 20
  54:	03 c0       	rjmp	.+6      	; 0x5c <__SREG__+0x1d>
    }
    else if(ch == STK_SET_DEVICE_EXT) {
  56:	85 34       	cpi	r24, 0x45	; 69
  58:	19 f4       	brne	.+6      	; 0x60 <__SREG__+0x21>
      // SET DEVICE EXT is ignored
      getNch(5);
  5a:	85 e0       	ldi	r24, 0x05	; 5
  5c:	03 d1       	rcall	.+518    	; 0x264 <getNch>
  5e:	c8 c0       	rjmp	.+400    	; 0x1f0 <__SREG__+0x1b1>
    }
    else if(ch == STK_LOAD_ADDRESS) {
  60:	85 35       	cpi	r24, 0x55	; 85
  62:	81 f4       	brne	.+32     	; 0x84 <__SREG__+0x45>
      // LOAD ADDRESS
      uint16_t newAddress;
      newAddress = getch();
  64:	d7 d0       	rcall	.+430    	; 0x214 <getch>
      newAddress = (newAddress & 0xff) | (getch() << 8);
  66:	08 2f       	mov	r16, r24
  68:	10 e0       	ldi	r17, 0x00	; 0
  6a:	d4 d0       	rcall	.+424    	; 0x214 <getch>
  6c:	90 e0       	ldi	r25, 0x00	; 0
  6e:	98 2f       	mov	r25, r24
  70:	88 27       	eor	r24, r24
  72:	80 2b       	or	r24, r16
  74:	91 2b       	or	r25, r17
#ifdef RAMPZ
      // Transfer top bit to RAMPZ
      RAMPZ = (newAddress & 0x8000) ? 1 : 0;
#endif
      newAddress += newAddress; // Convert from word address to byte address
  76:	88 0f       	add	r24, r24
  78:	99 1f       	adc	r25, r25
      address = newAddress;
  7a:	90 93 81 01 	sts	0x0181, r25
  7e:	80 93 80 01 	sts	0x0180, r24
  82:	b5 c0       	rjmp	.+362    	; 0x1ee <__SREG__+0x1af>
      verifySpace();
    }
    else if(ch == STK_UNIVERSAL) {
  84:	86 35       	cpi	r24, 0x56	; 86
  86:	29 f4       	brne	.+10     	; 0x92 <__SREG__+0x53>
      // UNIVERSAL command is ignored
      getNch(4);
  88:	84 e0       	ldi	r24, 0x04	; 4
  8a:	ec d0       	rcall	.+472    	; 0x264 <getNch>
      putch(0x00);
  8c:	80 e0       	ldi	r24, 0x00	; 0
  8e:	b3 d0       	rcall	.+358    	; 0x1f6 <putch>
  90:	af c0       	rjmp	.+350    	; 0x1f0 <__SREG__+0x1b1>
    }
    /* Write memory, length is big endian and is in bytes */
    else if(ch == STK_PROG_PAGE) {
  92:	84 36       	cpi	r24, 0x64	; 100
  94:	09 f0       	breq	.+2      	; 0x98 <__SREG__+0x59>
  96:	6b c0       	rjmp	.+214    	; 0x16e <__SREG__+0x12f>
      // PROGRAM PAGE - we support flash programming only, not EEPROM
      uint8_t *bufPtr;
      uint16_t addrPtr;

      getLen();
  98:	d1 d0       	rcall	.+418    	; 0x23c <getLen>
  9a:	c0 e0       	ldi	r28, 0x00	; 0
  9c:	d1 e0       	ldi	r29, 0x01	; 1
      // If we are in RWW section, immediately start page erase
      if (address < NRWWSTART) __boot_page_erase_short((uint16_t)(void*)address);

      // While that is going on, read in page contents
      bufPtr = buff;
      do *bufPtr++ = getch();
  9e:	ba d0       	rcall	.+372    	; 0x214 <getch>
  a0:	89 93       	st	Y+, r24
      while (--length);
  a2:	80 91 82 01 	lds	r24, 0x0182
  a6:	81 50       	subi	r24, 0x01	; 1
  a8:	80 93 82 01 	sts	0x0182, r24
  ac:	88 23       	and	r24, r24
  ae:	b9 f7       	brne	.-18     	; 0x9e <__SREG__+0x5f>

      // If we are in NRWW section, page erase has to be delayed until now.
      // Todo: Take RAMPZ into account
      if (address >= NRWWSTART) __boot_page_erase_short((uint16_t)(void*)address);
  b0:	e0 91 80 01 	lds	r30, 0x0180
  b4:	f0 91 81 01 	lds	r31, 0x0181
  b8:	83 e0       	ldi	r24, 0x03	; 3
  ba:	87 bf       	out	0x37, r24	; 55
  bc:	e8 95       	spm

      // Read command terminator, start reply
      verifySpace();
  be:	cc d0       	rcall	.+408    	; 0x258 <verifySpace>

      // If only a partial page is to be programmed, the erase might not be complete.
      // So check that here
      boot_spm_busy_wait();
  c0:	07 b6       	in	r0, 0x37	; 55
  c2:	00 fc       	sbrc	r0, 0
  c4:	fd cf       	rjmp	.-6      	; 0xc0 <__SREG__+0x81>

#ifdef VIRTUAL_BOOT_PARTITION
      if ((uint16_t)(void*)address == 0) {
  c6:	80 91 80 01 	lds	r24, 0x0180
  ca:	90 91 81 01 	lds	r25, 0x0181
  ce:	89 2b       	or	r24, r25
  d0:	41 f5       	brne	.+80     	; 0x122 <__SREG__+0xe3>
        // This is the reset vector page. We need to live-patch the code so the
        // bootloader runs.
        //
        // Move RESET vector to WDT vector
        uint16_t vect = buff[0] | (buff[1]<<8);
  d2:	80 91 00 01 	lds	r24, 0x0100
  d6:	20 91 01 01 	lds	r18, 0x0101
  da:	30 e0       	ldi	r19, 0x00	; 0
  dc:	32 2f       	mov	r19, r18
  de:	22 27       	eor	r18, r18
  e0:	90 e0       	ldi	r25, 0x00	; 0
  e2:	28 2b       	or	r18, r24
  e4:	39 2b       	or	r19, r25
        rstVect = vect;
  e6:	30 93 85 01 	sts	0x0185, r19
  ea:	20 93 84 01 	sts	0x0184, r18
        wdtVect = buff[8] | (buff[9]<<8);
  ee:	40 91 08 01 	lds	r20, 0x0108
  f2:	80 91 09 01 	lds	r24, 0x0109
  f6:	90 e0       	ldi	r25, 0x00	; 0
  f8:	98 2f       	mov	r25, r24
  fa:	88 27       	eor	r24, r24
  fc:	50 e0       	ldi	r21, 0x00	; 0
  fe:	84 2b       	or	r24, r20
 100:	95 2b       	or	r25, r21
 102:	90 93 87 01 	sts	0x0187, r25
 106:	80 93 86 01 	sts	0x0186, r24
        vect -= 4; // Instruction is a relative jump (rjmp), so recalculate.
 10a:	24 50       	subi	r18, 0x04	; 4
 10c:	30 40       	sbci	r19, 0x00	; 0
        buff[8] = vect & 0xff;
 10e:	20 93 08 01 	sts	0x0108, r18
        buff[9] = vect >> 8;
 112:	23 2f       	mov	r18, r19
 114:	33 27       	eor	r19, r19
 116:	20 93 09 01 	sts	0x0109, r18

        // Add jump to bootloader at RESET vector
        buff[0] = 0x7f;
 11a:	f0 92 00 01 	sts	0x0100, r15
        buff[1] = 0xce; // rjmp 0x1d00 instruction
 11e:	e0 92 01 01 	sts	0x0101, r14
      }
#endif

      // Copy buffer into programming buffer
      bufPtr = buff;
      addrPtr = (uint16_t)(void*)address;
 122:	40 91 80 01 	lds	r20, 0x0180
 126:	50 91 81 01 	lds	r21, 0x0181
 12a:	a0 e0       	ldi	r26, 0x00	; 0
 12c:	b1 e0       	ldi	r27, 0x01	; 1
      ch = SPM_PAGESIZE / 2;
      do {
        uint16_t a;
        a = *bufPtr++;
 12e:	2c 91       	ld	r18, X
 130:	30 e0       	ldi	r19, 0x00	; 0
        a |= (*bufPtr++) << 8;
 132:	11 96       	adiw	r26, 0x01	; 1
 134:	8c 91       	ld	r24, X
 136:	11 97       	sbiw	r26, 0x01	; 1
 138:	90 e0       	ldi	r25, 0x00	; 0
 13a:	98 2f       	mov	r25, r24
 13c:	88 27       	eor	r24, r24
 13e:	82 2b       	or	r24, r18
 140:	93 2b       	or	r25, r19
#define rstVect (*(uint16_t*)(RAMSTART+SPM_PAGESIZE*2+4))
#define wdtVect (*(uint16_t*)(RAMSTART+SPM_PAGESIZE*2+6))
#endif

/* main program starts here */
int main(void) {
 142:	12 96       	adiw	r26, 0x02	; 2
      ch = SPM_PAGESIZE / 2;
      do {
        uint16_t a;
        a = *bufPtr++;
        a |= (*bufPtr++) << 8;
        __boot_page_fill_short((uint16_t)(void*)addrPtr,a);
 144:	fa 01       	movw	r30, r20
 146:	0c 01       	movw	r0, r24
 148:	d7 be       	out	0x37, r13	; 55
 14a:	e8 95       	spm
 14c:	11 24       	eor	r1, r1
        addrPtr += 2;
 14e:	4e 5f       	subi	r20, 0xFE	; 254
 150:	5f 4f       	sbci	r21, 0xFF	; 255
      } while (--ch);
 152:	f1 e0       	ldi	r31, 0x01	; 1
 154:	a0 34       	cpi	r26, 0x40	; 64
 156:	bf 07       	cpc	r27, r31
 158:	51 f7       	brne	.-44     	; 0x12e <__SREG__+0xef>

      // Write from programming buffer
      __boot_page_write_short((uint16_t)(void*)address);
 15a:	e0 91 80 01 	lds	r30, 0x0180
 15e:	f0 91 81 01 	lds	r31, 0x0181
 162:	c7 be       	out	0x37, r12	; 55
 164:	e8 95       	spm
      boot_spm_busy_wait();
 166:	07 b6       	in	r0, 0x37	; 55
 168:	00 fc       	sbrc	r0, 0
 16a:	fd cf       	rjmp	.-6      	; 0x166 <__SREG__+0x127>
 16c:	41 c0       	rjmp	.+130    	; 0x1f0 <__SREG__+0x1b1>
      boot_rww_enable();
#endif

    }
    /* Read memory block mode, length is big endian.  */
    else if(ch == STK_READ_PAGE) {
 16e:	84 37       	cpi	r24, 0x74	; 116
 170:	89 f5       	brne	.+98     	; 0x1d4 <__SREG__+0x195>
      // READ PAGE - we only read flash
      getLen();
 172:	64 d0       	rcall	.+200    	; 0x23c <getLen>
      verifySpace();
 174:	71 d0       	rcall	.+226    	; 0x258 <verifySpace>
#ifdef VIRTUAL_BOOT_PARTITION
      do {
        // Undo vector patch in bottom page so verify passes
        if (address == 0)       ch=rstVect & 0xff;
 176:	e0 91 80 01 	lds	r30, 0x0180
 17a:	f0 91 81 01 	lds	r31, 0x0181
 17e:	30 97       	sbiw	r30, 0x00	; 0
 180:	19 f4       	brne	.+6      	; 0x188 <__SREG__+0x149>
 182:	20 91 84 01 	lds	r18, 0x0184
 186:	13 c0       	rjmp	.+38     	; 0x1ae <__SREG__+0x16f>
        else if (address == 1)  ch=rstVect >> 8;
 188:	e1 30       	cpi	r30, 0x01	; 1
 18a:	f1 05       	cpc	r31, r1
 18c:	19 f4       	brne	.+6      	; 0x194 <__SREG__+0x155>
 18e:	20 91 85 01 	lds	r18, 0x0185
 192:	0d c0       	rjmp	.+26     	; 0x1ae <__SREG__+0x16f>
        else if (address == 8)  ch=wdtVect & 0xff;
 194:	e8 30       	cpi	r30, 0x08	; 8
 196:	f1 05       	cpc	r31, r1
 198:	19 f4       	brne	.+6      	; 0x1a0 <__SREG__+0x161>
 19a:	20 91 86 01 	lds	r18, 0x0186
 19e:	07 c0       	rjmp	.+14     	; 0x1ae <__SREG__+0x16f>
        else if (address == 9) ch=wdtVect >> 8;
 1a0:	e9 30       	cpi	r30, 0x09	; 9
 1a2:	f1 05       	cpc	r31, r1
 1a4:	19 f4       	brne	.+6      	; 0x1ac <__SREG__+0x16d>
 1a6:	20 91 87 01 	lds	r18, 0x0187
 1aa:	01 c0       	rjmp	.+2      	; 0x1ae <__SREG__+0x16f>
        else ch = pgm_read_byte_near(address);
 1ac:	24 91       	lpm	r18, Z+
        address++;
 1ae:	80 91 80 01 	lds	r24, 0x0180
 1b2:	90 91 81 01 	lds	r25, 0x0181
 1b6:	01 96       	adiw	r24, 0x01	; 1
 1b8:	90 93 81 01 	sts	0x0181, r25
 1bc:	80 93 80 01 	sts	0x0180, r24
        putch(ch);
 1c0:	82 2f       	mov	r24, r18
 1c2:	19 d0       	rcall	.+50     	; 0x1f6 <putch>
      } while (--length);
 1c4:	80 91 82 01 	lds	r24, 0x0182
 1c8:	81 50       	subi	r24, 0x01	; 1
 1ca:	80 93 82 01 	sts	0x0182, r24
 1ce:	88 23       	and	r24, r24
 1d0:	91 f6       	brne	.-92     	; 0x176 <__SREG__+0x137>
 1d2:	0e c0       	rjmp	.+28     	; 0x1f0 <__SREG__+0x1b1>
#endif
#endif
    }

    /* Get device signature bytes  */
    else if(ch == STK_READ_SIGN) {
 1d4:	85 37       	cpi	r24, 0x75	; 117
 1d6:	39 f4       	brne	.+14     	; 0x1e6 <__SREG__+0x1a7>
      // READ SIGN - return what Avrdude wants to hear
      verifySpace();
 1d8:	3f d0       	rcall	.+126    	; 0x258 <verifySpace>
      putch(SIGNATURE_0);
 1da:	8e e1       	ldi	r24, 0x1E	; 30
 1dc:	0c d0       	rcall	.+24     	; 0x1f6 <putch>
      putch(SIGNATURE_1);
 1de:	83 e9       	ldi	r24, 0x93	; 147
 1e0:	0a d0       	rcall	.+20     	; 0x1f6 <putch>
      putch(SIGNATURE_2);
 1e2:	8c e0       	ldi	r24, 0x0C	; 12
 1e4:	54 cf       	rjmp	.-344    	; 0x8e <__SREG__+0x4f>
    }
    else if (ch == 'Q') {
 1e6:	81 35       	cpi	r24, 0x51	; 81
 1e8:	11 f4       	brne	.+4      	; 0x1ee <__SREG__+0x1af>
      // Adaboot no-wait mod
      watchdogConfig(WATCHDOG_16MS);
 1ea:	88 e0       	ldi	r24, 0x08	; 8
 1ec:	2c d0       	rcall	.+88     	; 0x246 <watchdogConfig>
      verifySpace();
    }
    else {
      // This covers the response to commands like STK_ENTER_PROGMODE
      verifySpace();
 1ee:	34 d0       	rcall	.+104    	; 0x258 <verifySpace>
    }
    putch(STK_OK);
 1f0:	80 e1       	ldi	r24, 0x10	; 16
 1f2:	01 d0       	rcall	.+2      	; 0x1f6 <putch>
 1f4:	25 cf       	rjmp	.-438    	; 0x40 <__SREG__+0x1>

000001f6 <putch>:
void putch(char ch) {
#ifndef SOFT_UART
  while (!(UCSR0A & _BV(UDRE0)));
  UDR0 = ch;
#else
  __asm__ __volatile__ (
 1f6:	2a e0       	ldi	r18, 0x0A	; 10
 1f8:	30 e0       	ldi	r19, 0x00	; 0
 1fa:	80 95       	com	r24
 1fc:	08 94       	sec
 1fe:	10 f4       	brcc	.+4      	; 0x204 <putch+0xe>
 200:	da 98       	cbi	0x1b, 2	; 27
 202:	02 c0       	rjmp	.+4      	; 0x208 <putch+0x12>
 204:	da 9a       	sbi	0x1b, 2	; 27
 206:	00 00       	nop
 208:	15 d0       	rcall	.+42     	; 0x234 <uartDelay>
 20a:	14 d0       	rcall	.+40     	; 0x234 <uartDelay>
 20c:	86 95       	lsr	r24
 20e:	2a 95       	dec	r18
 210:	b1 f7       	brne	.-20     	; 0x1fe <putch+0x8>
      [uartBit] "I" (UART_TX_BIT)
    :
      "r25"
  );
#endif
}
 212:	08 95       	ret

00000214 <getch>:
  return getch();
}

// Watchdog functions. These are only safe with interrupts turned off.
void watchdogReset() {
  __asm__ __volatile__ (
 214:	a8 95       	wdr
  LED_PIN |= _BV(LED);
#endif
#endif

  return ch;
}
 216:	29 e0       	ldi	r18, 0x09	; 9
 218:	30 e0       	ldi	r19, 0x00	; 0
 21a:	cb 99       	sbic	0x19, 3	; 25
 21c:	fe cf       	rjmp	.-4      	; 0x21a <getch+0x6>
 21e:	0a d0       	rcall	.+20     	; 0x234 <uartDelay>
 220:	09 d0       	rcall	.+18     	; 0x234 <uartDelay>
 222:	08 d0       	rcall	.+16     	; 0x234 <uartDelay>
 224:	88 94       	clc
 226:	cb 99       	sbic	0x19, 3	; 25
 228:	08 94       	sec
 22a:	2a 95       	dec	r18
 22c:	11 f0       	breq	.+4      	; 0x232 <getch+0x1e>
 22e:	87 95       	ror	r24
 230:	f7 cf       	rjmp	.-18     	; 0x220 <getch+0xc>
 232:	08 95       	ret

00000234 <uartDelay>:
#if UART_B_VALUE > 255
#error Baud rate too slow for soft UART
#endif

void uartDelay() {
  __asm__ __volatile__ (
 234:	9e e0       	ldi	r25, 0x0E	; 14
 236:	9a 95       	dec	r25
 238:	f1 f7       	brne	.-4      	; 0x236 <uartDelay+0x2>
 23a:	08 95       	ret

0000023c <getLen>:
  } while (--count);
}
#endif

uint8_t getLen() {
  getch();
 23c:	eb df       	rcall	.-42     	; 0x214 <getch>
  length = getch();
 23e:	ea df       	rcall	.-44     	; 0x214 <getch>
 240:	80 93 82 01 	sts	0x0182, r24
  return getch();
}
 244:	e7 cf       	rjmp	.-50     	; 0x214 <getch>

00000246 <watchdogConfig>:
    "wdr\n"
  );
}

void watchdogConfig(uint8_t x) {
  WDTCSR = _BV(WDCE) | _BV(WDE);
 246:	98 e1       	ldi	r25, 0x18	; 24
 248:	91 bd       	out	0x21, r25	; 33
  WDTCSR = x;
 24a:	81 bd       	out	0x21, r24	; 33
}
 24c:	08 95       	ret

0000024e <appStart>:

void appStart() {
  watchdogConfig(WATCHDOG_OFF);
 24e:	80 e0       	ldi	r24, 0x00	; 0
 250:	fa df       	rcall	.-12     	; 0x246 <watchdogConfig>
  __asm__ __volatile__ (
 252:	e4 e0       	ldi	r30, 0x04	; 4
 254:	ff 27       	eor	r31, r31
 256:	09 94       	ijmp

00000258 <verifySpace>:
  do getch(); while (--count);
  verifySpace();
}

void verifySpace() {
  if (getch() != CRC_EOP) appStart();
 258:	dd df       	rcall	.-70     	; 0x214 <getch>
 25a:	80 32       	cpi	r24, 0x20	; 32
 25c:	09 f0       	breq	.+2      	; 0x260 <verifySpace+0x8>
 25e:	f7 df       	rcall	.-18     	; 0x24e <appStart>
  putch(STK_INSYNC);
 260:	84 e1       	ldi	r24, 0x14	; 20
}
 262:	c9 cf       	rjmp	.-110    	; 0x1f6 <putch>

00000264 <getNch>:
    ::[count] "M" (UART_B_VALUE)
  );
}
#endif

void getNch(uint8_t count) {
 264:	1f 93       	push	r17
 266:	18 2f       	mov	r17, r24
  do getch(); while (--count);
 268:	d5 df       	rcall	.-86     	; 0x214 <getch>
 26a:	11 50       	subi	r17, 0x01	; 1
 26c:	e9 f7       	brne	.-6      	; 0x268 <getNch+0x4>
  verifySpace();
 26e:	f4 df       	rcall	.-24     	; 0x258 <verifySpace>
}
 270:	1f 91       	pop	r17
 272:	08 95       	ret