/* * Project: Micronucleus - v2.0 * * Micronucleus V2.0 (c) 2014 Tim Bo"scke - cpldcpu@gmail.com * (c) 2014 Shay Green * Original Micronucleus (c) 2012 Jenna Fox * * Based on USBaspLoader-tiny85 (c) 2012 Louis Beaudoin * Based on USBaspLoader (c) 2007 by OBJECTIVE DEVELOPMENT Software GmbH * * License: GNU GPL v2 (see License.txt) */ #define MICRONUCLEUS_VERSION_MAJOR 2 #define MICRONUCLEUS_VERSION_MINOR 0 #include #include #include #include #include #include "bootloaderconfig.h" #include "usbdrv/usbdrv.c" // 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 5 // 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 #if SPM_PAGESIZE>256 #error "Micronucleus only supports pagesizes up to 256 bytes" #endif // Device configuration reply // Length: 4 bytes // Byte 0: User program memory size, high byte // Byte 1: User program memory size, low byte // Byte 2: Flash Pagesize in bytes // Byte 3: Page write timing in ms PROGMEM const uint8_t configurationReply[4] = { (((uint16_t)PROGMEM_SIZE) >> 8) & 0xff, ((uint16_t)PROGMEM_SIZE) & 0xff, SPM_PAGESIZE, MICRONUCLEUS_WRITE_SLEEP }; #if OSCCAL_RESTORE register uint8_t osccal_default asm("r2"); #endif register uint16_union_t currentAddress asm("r4"); // r4/r5 current progmem address, used for erasing and writing register uint16_union_t idlePolls asm("r6"); // r6/r7 idlecounter // command system schedules functions to run in the main loop enum { cmd_local_nop=0, // also: get device info cmd_device_info=0, cmd_transfer_page=1, cmd_erase_application=2, cmd_write_data=3, cmd_exit=4, cmd_write_page=64, // internal commands start at 64 }; register uint8_t command asm("r3"); // bind command to r3 // 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") #define nop() asm volatile("nop") // Use the old delay routines without NOP padding. This saves memory. #define __DELAY_BACKWARD_COMPATIBLE__ /* ------------------------------------------------------------------------ */ static inline void eraseApplication(void); static void writeFlashPage(void); static void writeWordToPageBuffer(uint16_t data); static uint8_t usbFunctionSetup(uint8_t data[8]); static inline void leaveBootloader(void); // This function is never called, it is just here to suppress a compiler warning. USB_PUBLIC usbMsgLen_t usbFunctionDescriptor(struct usbRequest *rq) { return 0; } // 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))) \ ); \ })) // 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; while (ptr) { ptr -= SPM_PAGESIZE; boot_page_erase(ptr); } // clear page buffer as a precaution before filling the buffer in case // a previous write operation failed and there is still something in the buffer. __boot_page_fill_clear(); // Write reset vector into first page. currentAddress.w = 0; writeWordToPageBuffer(0xffff); command=cmd_write_page; } // simply write currently stored page in to already erased flash memory static inline void writeFlashPage(void) { if (currentAddress.w - 2 bRequest == cmd_device_info) { // get device info usbMsgPtr = (usbMsgPtr_t)configurationReply; return sizeof(configurationReply); } else if (rq->bRequest == cmd_transfer_page) { // initialize write page currentAddress.w = rq->wIndex.word; } else if (rq->bRequest == cmd_write_data) { // Write data writeWordToPageBuffer(rq->wValue.word); writeWordToPageBuffer(rq->wIndex.word); if ((currentAddress.b[0] % SPM_PAGESIZE) == 0) command=cmd_write_page; // ask runloop to write our page } else { // Handle cmd_erase_application and cmd_exit command=rq->bRequest; } return 0; } static void initHardware (void) { // Disable watchdog and set timeout to maximum in case the WDT is fused on MCUSR=0; WDTCR = 1<0) { idlePolls.b[1]=((AUTO_EXIT_MS-AUTO_EXIT_NO_USB_MS) * 10UL)>>8; } else { idlePolls.b[1]=0; } do { // 15 clockcycles per loop. // adjust fastctr for 1ms timeout uint16_t fastctr=(uint16_t)(F_CPU/(1000.0f*15.0f)); uint8_t resetctr=20; do { if ((USBIN & USBMASK) !=0) resetctr=20; if (!--resetctr) { // reset encountered usbNewDeviceAddr = 0; // bits from the reset handling of usbpoll() usbDeviceAddr = 0; calibrateOscillatorASM(); } if (USB_INTR_PENDING & (1<