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/* Name: main.c
* Project: Micronucleus
* Author: Jenna Fox
* Creation Date: 2007-12-08
* Tabsize: 4
* Copyright: (c) 2012 Jenna Fox
* All changes past revision 1.06 authored by http://github.com/cpldcpu
* Portions Copyright: (c) 2007 by OBJECTIVE DEVELOPMENT Software GmbH (USBaspLoader)
* Portions Copyright: (c) 2012 Louis Beaudoin (USBaspLoader-tiny85)
* License: GNU GPL v2 (see License.txt)
*
*/
#define MICRONUCLEUS_VERSION_MAJOR 1
#define MICRONUCLEUS_VERSION_MINOR 10
// how many milliseconds should host wait till it sends another erase or write?
// needs to be above 4.5 (and a whole integer) as avr freezes for 4.5ms
#define MICRONUCLEUS_WRITE_SLEEP 8
// Use the old delay routines without NOP padding. This saves memory.
#define __DELAY_BACKWARD_COMPATIBLE__
#include <avr/io.h>
#include <avr/pgmspace.h>
#include <avr/wdt.h>
#include <avr/boot.h>
#include <util/delay.h>
#include "bootloaderconfig.h"
#include "usbdrv/usbdrv.c"
/* ------------------------------------------------------------------------ */
// postscript are the few bytes at the end of programmable memory which store tinyVectors
// and used to in USBaspLoader-tiny85 store the checksum iirc
#define POSTSCRIPT_SIZE 6
#define PROGMEM_SIZE (BOOTLOADER_ADDRESS - POSTSCRIPT_SIZE) /* max size of user program */
// verify the bootloader address aligns with page size
#if BOOTLOADER_ADDRESS % SPM_PAGESIZE != 0
# error "BOOTLOADER_ADDRESS in makefile must be a multiple of chip's pagesize"
#endif
#ifdef AUTO_EXIT_MS
# if AUTO_EXIT_MS < (MICRONUCLEUS_WRITE_SLEEP * (BOOTLOADER_ADDRESS / SPM_PAGESIZE))
# warning "AUTO_EXIT_MS is shorter than the time it takes to perform erase function - might affect reliability?"
# warning "Try increasing AUTO_EXIT_MS if you have stability problems"
# endif
#endif
// events system schedules functions to run in the main loop
// static uint8_t events = 0; // bitmap of events to run
register uint8_t events asm( "r3" ); // register saves many bytes
#define EVENT_ERASE_APPLICATION 1
#define EVENT_WRITE_PAGE 2
#define EVENT_EXECUTE 4
// controls state of events
#define fireEvent(event) events |= (event)
#define isEvent(event) (events & (event))
#define clearEvents() events = 0
// Definition of sei and cli without memory barrier keyword to prevent reloading of memory variables
#define sei() __asm__ __volatile__ ("sei")
#define cli() __asm__ __volatile__ ("cli")
uint16_t idlePolls = 0; // how long have we been idle?
static uint16_t vectorTemp[2]; // remember data to create tinyVector table before BOOTLOADER_ADDRESS
static uint16_t currentAddress; // current progmem address, used for erasing and writing
#if OSCCAL_RESTORE
static uint8_t osccal_default; // due to compiler insanity, having this as global actually saves memory
#endif
/* ------------------------------------------------------------------------ */
static inline void eraseApplication(void);
static void writeFlashPage(void);
static void writeWordToPageBuffer(uint16_t data);
static uint8_t usbFunctionSetup(uint8_t data[8]);
static uint8_t usbFunctionWrite(uint8_t *data, uint8_t length);
static inline void leaveBootloader(void);
// erase any existing application and write in jumps for usb interrupt and reset to bootloader
// - Because flash can be erased once and programmed several times, we can write the bootloader
// - vectors in now, and write in the application stuff around them later.
// - if vectors weren't written back in immediately, usb would fail.
static inline void eraseApplication(void) {
// erase all pages until bootloader, in reverse order (so our vectors stay in place for as long as possible)
// while the vectors don't matter for usb comms as interrupts are disabled during erase, it's important
// to minimise the chance of leaving the device in a state where the bootloader wont run, if there's power failure
// during upload
uint8_t i;
uint16_t ptr = BOOTLOADER_ADDRESS;
cli();
while (ptr) {
ptr -= SPM_PAGESIZE;
boot_page_erase(ptr);
}
currentAddress = 0;
for (i=0; i<8; i++) writeWordToPageBuffer(0xFFFF); // Write first 8 words to fill in vectors.
writeFlashPage(); // enables interrupts
}
// simply write currently stored page in to already erased flash memory
static void writeFlashPage(void) {
cli();
boot_page_write(currentAddress - 2); // will halt CPU, no waiting required
sei();
}
// clear memory which stores data to be written by next writeFlashPage call
#define __boot_page_fill_clear() \
(__extension__({ \
__asm__ __volatile__ \
( \
"sts %0, %1\n\t" \
"spm\n\t" \
: \
: "i" (_SFR_MEM_ADDR(__SPM_REG)), \
"r" ((uint8_t)(__BOOT_PAGE_FILL | (1 << CTPB))) \
); \
}))
// write a word in to the page buffer, doing interrupt table modifications where they're required
static void writeWordToPageBuffer(uint16_t data) {
uint8_t previous_sreg;
// first two interrupt vectors get replaced with a jump to the bootloader's vector table
// remember vectors or the tinyvector table
if (currentAddress == RESET_VECTOR_OFFSET * 2) {
vectorTemp[0] = data;
data = 0xC000 + (BOOTLOADER_ADDRESS/2) - 1;
}
if (currentAddress == USBPLUS_VECTOR_OFFSET * 2) {
vectorTemp[1] = data;
data = 0xC000 + (BOOTLOADER_ADDRESS/2) - 1;
}
// at end of page just before bootloader, write in tinyVector table
// see http://embedded-creations.com/projects/attiny85-usb-bootloader-overview/avr-jtag-programmer/
// for info on how the tiny vector table works
if (currentAddress == BOOTLOADER_ADDRESS - TINYVECTOR_RESET_OFFSET) {
data = vectorTemp[0] + ((FLASHEND + 1) - BOOTLOADER_ADDRESS)/2 + 2 + RESET_VECTOR_OFFSET;
} else if (currentAddress == BOOTLOADER_ADDRESS - TINYVECTOR_USBPLUS_OFFSET) {
data = vectorTemp[1] + ((FLASHEND + 1) - BOOTLOADER_ADDRESS)/2 + 1 + USBPLUS_VECTOR_OFFSET;
#if (!OSCCAL_RESTORE) && OSCCAL_16_5MHz
} else if (currentAddress == BOOTLOADER_ADDRESS - TINYVECTOR_OSCCAL_OFFSET) {
data = OSCCAL;
#endif
}
previous_sreg=SREG;
cli(); // ensure interrupts are disabled
boot_page_fill(currentAddress, data);
// increment progmem address by one word
currentAddress += 2;
SREG=previous_sreg;
}
/* ------------------------------------------------------------------------ */
static uint8_t usbFunctionSetup(uint8_t data[8]) {
usbRequest_t *rq = (void *)data;
((uint8_t*)&idlePolls)[1] = 0; // reset idle polls when we get usb traffic
static uint8_t replyBuffer[4] = {
(((uint16_t)PROGMEM_SIZE) >> 8) & 0xff,
((uint16_t)PROGMEM_SIZE) & 0xff,
SPM_PAGESIZE,
MICRONUCLEUS_WRITE_SLEEP
};
if (rq->bRequest == 0) { // get device info
usbMsgPtr = replyBuffer;
return 4;
} else if (rq->bRequest == 1) { // write page
currentAddress = rq->wIndex.word;
return USB_NO_MSG; // hands off work to usbFunctionWrite
} else if (rq->bRequest == 2) { // erase application
fireEvent(EVENT_ERASE_APPLICATION);
} else { // exit bootloader
# if BOOTLOADER_CAN_EXIT
fireEvent(EVENT_EXECUTE);
# endif
}
return 0;
}
// read in a page over usb, and write it in to the flash write buffer
static uint8_t usbFunctionWrite(uint8_t *data, uint8_t length) {
do {
// make sure we don't write over the bootloader!
if (currentAddress >= BOOTLOADER_ADDRESS) break;
writeWordToPageBuffer(*(uint16_t *) data);
data += 2; // advance data pointer
length -= 2;
} while(length);
// if we have now reached another page boundary, we're done
#if SPM_PAGESIZE<256
// Hack to reduce code size
uint8_t isLast = ((((uint8_t)currentAddress) % SPM_PAGESIZE) == 0);
#else
uint8_t isLast = ((currentAddress % SPM_PAGESIZE) == 0);
#endif
// definitely need this if! seems usbFunctionWrite gets called again in future usbPoll's in the runloop!
if (isLast) fireEvent(EVENT_WRITE_PAGE); // ask runloop to write our page
return isLast; // let vusb know we're done with this request
}
/* ------------------------------------------------------------------------ */
void PushMagicWord (void) __attribute__ ((naked)) __attribute__ ((section (".init3")));
// put the word "B007" at the bottom of the stack (RAMEND - RAMEND-1)
void PushMagicWord (void) {
asm volatile("ldi r16, 0xB0"::);
asm volatile("push r16"::);
asm volatile("ldi r16, 0x07"::);
asm volatile("push r16"::);
}
static void initHardware (void)
{
MCUSR=0; /* need this to properly disable watchdog */
wdt_disable();
#if LOW_POWER_MODE
// turn off clock prescalling - chip must run at full speed for usb
// if you might run chip at lower voltages, detect that in bootLoaderStartCondition
CLKPR = 1 << CLKPCE;
CLKPR = 0;
#endif
// clear page buffer as a precaution before filling the buffer on the first page
// in case the bootloader somehow ran after user program and there was something
// in the page buffer already
__boot_page_fill_clear();
usbDeviceDisconnect(); /* do this while interrupts are disabled */
_delay_ms(500);
usbDeviceConnect();
usbInit(); // Initialize INT settings after reconnect
sei();
}
/* ------------------------------------------------------------------------ */
// reset system to a normal state and launch user program
static void leaveBootloader(void) __attribute__((__noreturn__));
static inline void leaveBootloader(void) {
_delay_ms(10); // removing delay causes USB errors
bootLoaderExit();
cli();
usbDeviceDisconnect(); /* Disconnect micronucleus */
USB_INTR_ENABLE = 0;
USB_INTR_CFG = 0; /* also reset config bits */
// clear magic word from bottom of stack before jumping to the app
*(uint8_t*)(RAMEND) = 0x00; // A single write is sufficient to invalidate magic word
#if (!OSCCAL_RESTORE) && OSCCAL_16_5MHz
// adjust clock to previous calibration value, so user program always starts with same calibration
// as when it was uploaded originally
unsigned char stored_osc_calibration = pgm_read_byte(BOOTLOADER_ADDRESS - TINYVECTOR_OSCCAL_OFFSET);
if (stored_osc_calibration != 0xFF && stored_osc_calibration != 0x00) {
OSCCAL=stored_osc_calibration;
asm volatile("nop");
}
#endif
// jump to application reset vector at end of flash
asm volatile ("rjmp __vectors - 4");
}
int main(void) {
/* initialize */
#if OSCCAL_RESTORE
osccal_default = OSCCAL;
#endif
#if (!SET_CLOCK_PRESCALER) && LOW_POWER_MODE
uint8_t prescaler_default = CLKPR;
#endif
bootLoaderInit();
# if AUTO_EXIT_NO_USB_MS
((uint8_t*)&idlePolls)[1]=((AUTO_EXIT_MS-AUTO_EXIT_NO_USB_MS) * 10UL)>>8; // write only high byte to save 6 bytes
# endif
if (bootLoaderStartCondition()) {
initHardware();
# if LED_PRESENT
LED_INIT();
# endif
do {
clearEvents();
usbPoll();
_delay_us(100);
// these next two freeze the chip for ~ 4.5ms, breaking usb protocol
// and usually both of these will activate in the same loop, so host
// needs to wait > 9ms before next usb request
if (isEvent(EVENT_ERASE_APPLICATION)) eraseApplication();
if (isEvent(EVENT_WRITE_PAGE)) {
_delay_us(2000); // Wait for USB traffic to finish before halting CPU with write-
writeFlashPage();
}
# if LED_PRESENT
LED_MACRO( ((uint8_t*)&idlePolls)[1] )
# endif
// Only try to execute program if reset vector is set - bootloader will not time out with erased memory
if (!bootLoaderCondition()&&(pgm_read_byte(BOOTLOADER_ADDRESS - TINYVECTOR_RESET_OFFSET)!=0xff)) fireEvent(EVENT_EXECUTE);
} while(!isEvent(EVENT_EXECUTE)); /* main event loop runs as long as program is not executed */
}
// set clock prescaler to desired clock speed (changing from clkdiv8, or no division, depending on fuses)
#if LOW_POWER_MODE
#ifdef SET_CLOCK_PRESCALER
CLKPR = 1 << CLKPCE;
CLKPR = SET_CLOCK_PRESCALER;
#else
CLKPR = 1 << CLKPCE;
CLKPR = prescaler_default;
#endif
#endif
# if LED_PRESENT
LED_EXIT();
# endif
# if OSCCAL_RESTORE
OSCCAL=osccal_default;
asm volatile("nop"); // NOP to avoid CPU hickup during oscillator stabilization
# endif
leaveBootloader();
}
/* ------------------------------------------------------------------------ */
|