/* Name: bootloaderconfig.h * Micronucleus configuration file. * This file (together with some settings in Makefile) configures the boot loader * according to the hardware. * * Controller type: ATtiny 85 * Configuration: Digispark default configuration. * Last Change: Feb 21,2014 * * License: GNU GPL v2 (see License.txt */ #ifndef __bootloaderconfig_h_included__ #define __bootloaderconfig_h_included__ /* ------------------------------------------------------------------------- */ /* Hardware configuration. */ /* Change this according to your CPU and USB configuration */ /* ------------------------------------------------------------------------- */ #define USB_CFG_IOPORTNAME B /* This is the port where the USB bus is connected. When you configure it to * "B", the registers PORTB, PINB and DDRB will be used. */ #define USB_CFG_DMINUS_BIT 3 /* This is the bit number in USB_CFG_IOPORT where the USB D- line is connected. * This may be any bit in the port. */ #define USB_CFG_DPLUS_BIT 4 /* This is the bit number in USB_CFG_IOPORT where the USB D+ line is connected. * This may be any bit in the port, but must be configured as a pin change interrupt. */ #define USB_CFG_CLOCK_KHZ (F_CPU/1000) /* Clock rate of the AVR in kHz. Legal values are 12000, 12800, 15000, 16000, * 16500, 18000 and 20000. The 12.8 MHz and 16.5 MHz versions of the code * require no crystal, they tolerate +/- 1% deviation from the nominal * frequency. All other rates require a precision of 2000 ppm and thus a * crystal! * Since F_CPU should be defined to your actual clock rate anyway, you should * not need to modify this setting. */ /* ------------- Set up interrupt configuration (CPU specific) -------------- */ /* The register names change quite a bit in the ATtiny family. Pay attention */ /* to the manual. Note that the interrupt flag system is still used even though */ /* interrupts are disabled. So this has to be configured correctly. */ // setup interrupt for Pin Change for D+ #define USB_INTR_CFG PCMSK #define USB_INTR_CFG_SET (1 << USB_CFG_DPLUS_BIT) #define USB_INTR_CFG_CLR 0 #define USB_INTR_ENABLE GIMSK #define USB_INTR_ENABLE_BIT PCIE #define USB_INTR_PENDING GIFR #define USB_INTR_PENDING_BIT PCIF #define USB_INTR_VECTOR PCINT0_vect /* ------------------------------------------------------------------------- */ /* ---------------------- feature / code size options ---------------------- */ /* Configure the behavior of the bootloader here */ /* ------------------------------------------------------------------------- */ /* * Define Bootloader entry condition * * If the entry condition is not met, the bootloader will not be activated and the user program * is executed directly after a reset. If no user program has been loaded, the bootloader * is always active. * * ENTRY_ALWAYS Always activate the bootloader after reset. Requires the least * amount of code. * * ENTRY_WATCHDOG Activate the bootloader after a watchdog reset. This can be used * to enter the bootloader from the user program. * Adds 22 bytes. * * ENTRY_EXT_RESET Activate the bootloader after an external reset was issued by * pulling the reset pin low. It may be necessary to add an external * pull-up resistor to the reset pin if this entry method appears to * behave unreliably. * Adds 22 bytes. * * ENTRY_JUMPER Activate the bootloader when a specific pin is pulled low by an * external jumper. * Adds 34 bytes. * * JUMPER_PIN Pin the jumper is connected to. (e.g. PB0) * JUMPER_PORT Port out register for the jumper (e.g. PORTB) * JUMPER_DDR Port data direction register for the jumper (e.g. DDRB) * JUMPER_INP Port inout register for the jumper (e.g. PINB) * */ #define ENTRYMODE ENTRY_ALWAYS #define JUMPER_PIN PB0 #define JUMPER_PORT PORTB #define JUMPER_DDR DDRB #define JUMPER_INP PINB /* Internal implementation, don't change this unless you want to add an entrymode. */ #define ENTRY_ALWAYS 1 #define ENTRY_WATCHDOG 2 #define ENTRY_EXT_RESET 3 #define ENTRY_JUMPER 4 #if ENTRYMODE==ENTRY_ALWAYS #define bootLoaderInit() #define bootLoaderExit() #define bootLoaderStartCondition() 1 #elif ENTRYMODE==ENTRY_WATCHDOG #define bootLoaderInit() #define bootLoaderExit() #define bootLoaderStartCondition() (MCUSR&_BV(WDRF)) #elif ENTRYMODE==ENTRY_EXT_RESET #define bootLoaderInit() #define bootLoaderExit() #define bootLoaderStartCondition() (MCUSR&_BV(EXTRF)) #elif ENTRYMODE==ENTRY_JUMPER // Enable pull up on jumper pin and delay to stabilize input #define bootLoaderInit() {JUMPER_DDR&=~_BV(JUMPER_PIN);JUMPER_PORT|=_BV(JUMPER_PIN);_delay_ms(1);} #define bootLoaderExit() {JUMPER_PORT&=~_BV(JUMPER_PIN);} #define bootLoaderStartCondition() (!(JUMPER_INP&_BV(JUMPER_PIN))) #else #error "No entry mode defined" #endif /* * Define bootloader timeout value. * * The bootloader will only time out if a user program was loaded. * * AUTO_EXIT_NO_USB_MS The bootloader will exit after this delay if no USB is connected. * Set to 0 to disable * Adds ~6 bytes. * (This will wait for an USB SE0 reset from the host) * * AUTO_EXIT_MS The bootloader will exit after this delay if no USB communication * from the host tool was received. * Set to 0 to disable * * All values are approx. in milliseconds */ #define AUTO_EXIT_NO_USB_MS 0 #define AUTO_EXIT_MS 5000 /* * Defines the setting of the RC-oscillator calibration after quitting the bootloader. (OSCCAL) * * OSCCAL_RESTORE Set this to '1' to revert to factory calibration, which is 16.0 MHZ +/-10% * Adds ~14 bytes. * * OSCCAL_16.5MHz Set this to '1' to use the same calibration as during program upload. * This value is 16.5Mhz +/-1% as calibrated from the USB timing. Please note * that only true if the ambient temperature does not change. * This is the default behaviour of the original Digispark and is not recommended * for use on devices other than the ATtiny85. * Adds ~38 bytes. * * OSCCAL_HAVE_XTAL Set this to '1' if you have an external crystal oscillator. In this case no attempt * will be made to calibrate the oscillator. You should deactivate both options above * if you use this to avoid redundant code. * * If both options are selected, OSCCAL_RESTORE takes precedence. * * If no option is selected, OSCCAL will be left untouched and stays at either 16.0 Mhz or 16.5 Mhz depending * on whether the bootloader was activated. This will take the least memory. You can use this if your program * comes with its own OSCCAL calibration or an external clock source is used. */ #define OSCCAL_RESTORE 0 #define OSCCAL_16_5MHz 1 #define OSCCAL_HAVE_XTAL 0 /* * Defines handling of an indicator LED while the bootloader is active. * * LED_MODE Define behavior of attached LED or suppress LED code. * * NONE Do not generate LED code (gains 18 bytes). * ACTIVE_HIGH LED is on when output pin is high. This will toggle bettwen 1 and 0. * ACTIVE_LOW LED is on when output pin is low. This will toggle between Z and 0. * * LED_DDR,LED_PORT,LED_PIN Where is your LED connected? * */ #define LED_MODE ACTIVE_HIGH #define LED_DDR DDRB #define LED_PORT PORTB #define LED_PIN PB1 /* * This is the implementation of the LED code. Change the configuration above unless you want to * change the led behavior * * LED_INIT Called once after bootloader entry * LED_EXIT Called once during bootloader exit * LED_MACRO Called in the main loop with the idle counter as parameter. * Use to define pattern. */ #define NONE 0 #define ACTIVE_HIGH 1 #define ACTIVE_LOW 2 #if LED_MODE==ACTIVE_HIGH #define LED_INIT(x) LED_DDR = _BV(LED_PIN); #define LED_EXIT(x) {LED_DDR &=~_BV(LED_PIN);LED_PORT &=~_BV(LED_PIN);} #define LED_MACRO(x) if ( x & 0x4c ) {LED_PORT&=~_BV(LED_PIN);} else {LED_PORT|=_BV(LED_PIN);} #elif LED_MODE==ACTIVE_LOW #define LED_INIT(x) LED_PORT &=~_BV(LED_PIN); #define LED_EXIT(x) LED_DDR &=~_BV(LED_PIN); #define LED_MACRO(x) if ( x & 0x4c ) {LED_DDR&=~_BV(LED_PIN);} else {LED_DDR|=_BV(LED_PIN);} #elif LED_MODE==NONE #define LED_INIT(x) #define LED_EXIT(x) #define LED_MACRO(x) #endif /* --------------------------------------------------------------------------- */ /* Micronucleus internal configuration. Do not change anything below this line */ /* --------------------------------------------------------------------------- */ // Microcontroller vectortable entries in the flash #define RESET_VECTOR_OFFSET 0 // number of bytes before the boot loader vectors to store the tiny application vector table #define TINYVECTOR_RESET_OFFSET 4 #define TINYVECTOR_OSCCAL_OFFSET 6 /* ------------------------------------------------------------------------ */ // postscript are the few bytes at the end of programmable memory which store tinyVectors #define POSTSCRIPT_SIZE 6 #define PROGMEM_SIZE (BOOTLOADER_ADDRESS - POSTSCRIPT_SIZE) /* max size of user program */ #endif /* __bootloader_h_included__ */