A fork of Erik Olieman's bootloader for the KL05Z32. The bootloader is placed in the 29th sector allowing for 28kB of program memory. The 32nd sector is left empty after the bootloader to allow for use of the non volatile storage without the risk of overwriting it during serial firmware update.
Fork of Bootloader_K64F by
This is a simple boot loader which resides at the end of the flash banks of your uController. It has be ported to work with the KL05Z. Porting the code to another Free scale uController requires the following changes:
Step 1 Change the address of the following function address
If your uController of choice has a flash size other than 32kB then you will likely want to change the addresses of following functions (current addresses displayed).
bootloader.cpp 0x7000 bootloader 0x7080 setupserial 0x70A0 write FreescaleIAP.cpp 0x7268 erase_sector 0x7300 program_flash 0x7500 flash_size 0x7600 program_word 0x7700 run_command 0x7800 check_boundary 0x7900 check_align 0x7A00 verify_erased 0x7B00 check_error
Step 2 Follow the serial_api HAL file of your target
You will be unable to access anything that you don't define yourself in the bootloader. For this reason you need to create a function for serial. Look up and follow your target's serial_api.c file.
__attribute__((section(".ARM.__at_0x7080"))) static void setupserial(void) { //Setup USBRX/USBTX pins (PTB1/PTB2) //Enable Port B Clock SIM->SCGC5 |= 1 <<SIM_SCGC5_PORTB_SHIFT; //Select MCGFLLCLK clock SIM->SOPT2 |= 1 <<SIM_SOPT2_UART0SRC_SHIFT; //Select Pins PB1 & PB2 to their ALT3 function (RX & TX respectively) PORTB->PCR[1] = (PORTB->PCR[1] & ~0x700) | (3 << 8); PORTB->PCR[2] = (PORTB->PCR[2] & ~0x700) | (3 << 8); //Set UART0 Clock to be enabled SIM->SCGC4 |= SIM_SCGC4_UART0_MASK; //Set UART Baud Rate Register //Value's gathered expirimentally UART0->BDH = 1; UART0->BDL = 56; //Enable UART0 UART0->C2 |= (UARTLP_C2_RE_MASK | UARTLP_C2_TE_MASK); }
To set the correct baudrate you need to determine the right values for BDH & BDL registers for your clock speed. An easy way to do that is by simply printing them with the clock speed that you want like so:
#include "mbed.h" Serial pc(USBTX, USBrX); int main() { while (1) { pc.printf("BDH: %d \n", UART0->BDH); // print the value of BDH Register pc.printf("BDL: %d \n", UART0->BDL); // print the value of BDL Register pc.printf("SOPT2: %d \n", SIM->SOPT2); // print the value of SOPT2 Register pc.printf("SCGC5: %d \n", SIM->SCGC5); // print the value of SCGC5 Register pc.printf("SCGC4: %d \n", SIM->SCGC4); // print the value of SCGC4 Register pc.printf("C2: %d \n", UART0->C2); // print the value of C2 Register pc.printf("C4: %d \n", UART0->C4); // print the value of C4 Register wait(.5); } }
Step 3 Include bootloader.cpp in your first firmware
Before you can update firmware using serial you first must update the firmware using SWD along with the bootloader included in your binary.
#include "mbed.h" extern void bootloader(void); //... main(){ //... bootloader(); }
Step 4 Include reference to bootloader in serial updates
Once the bootloader is on the uControler you should not include the bootloader in binaries that you want to update over serial. Instead you can access the bootloader by using the following:
#include "mbed.h" void *(*bootloader)(void) = (void *(*)(void))0x7001; //Address of bootloader + 1 (For some reason) //... main(){ //... bootloader(); }
IF YOU ARE PROGRAMMING USING A PROGRAMMER (SWD OR JTAG) AND NOT SERIAL MAKE SURE TO INCLUDE THE BOOTLOADER OR OTHERWISE IT WILL MOST LIKELY BE ERASED OR OVERWRITTEN
FreescaleIAP/FreescaleIAP.cpp
- Committer:
- Dot
- Date:
- 2016-07-18
- Revision:
- 16:30f4c724da60
- Parent:
- 15:89e2c76e5eed
- Child:
- 18:c9396799d565
File content as of revision 16:30f4c724da60:
#include "FreescaleIAP.h" //#define IAPDEBUG #ifdef TARGET_K64F //For K64F # include "MK64F12.h" # define USE_ProgramPhrase 1 # define FTFA FTFE # define FTFA_FSTAT_FPVIOL_MASK FTFE_FSTAT_FPVIOL_MASK # define FTFA_FSTAT_ACCERR_MASK FTFE_FSTAT_ACCERR_MASK # define FTFA_FSTAT_RDCOLERR_MASK FTFE_FSTAT_RDCOLERR_MASK # define FTFA_FSTAT_CCIF_MASK FTFE_FSTAT_CCIF_MASK # define FTFA_FSTAT_MGSTAT0_MASK FTFE_FSTAT_MGSTAT0_MASK #else //Different names used on at least the K20: # ifndef FTFA_FSTAT_FPVIOL_MASK # define FTFA FTFL # define FTFA_FSTAT_FPVIOL_MASK FTFL_FSTAT_FPVIOL_MASK # define FTFA_FSTAT_ACCERR_MASK FTFL_FSTAT_ACCERR_MASK # define FTFA_FSTAT_RDCOLERR_MASK FTFL_FSTAT_RDCOLERR_MASK # define FTFA_FSTAT_CCIF_MASK FTFL_FSTAT_CCIF_MASK # define FTFA_FSTAT_MGSTAT0_MASK FTFL_FSTAT_MGSTAT0_MASK # endif #endif enum FCMD { Read1s = 0x01, ProgramCheck = 0x02, ReadResource = 0x03, ProgramLongword = 0x06, ProgramPhrase = 0x07, EraseSector = 0x09, Read1sBlock = 0x40, ReadOnce = 0x41, ProgramOnce = 0x43, EraseAll = 0x44, VerifyBackdoor = 0x45 }; inline void run_command(void); bool check_boundary(int address, unsigned int length); bool check_align(int address); IAPCode verify_erased(int address, unsigned int length); IAPCode check_error(void); IAPCode program_word(int address, char *data); __attribute__((section(".ARM.__at_0x7260"))) IAPCode erase_sector(int address) { #ifdef IAPDEBUG printf("IAP: Erasing at %x\r\n", address); #endif if (check_align(address)) return AlignError; //Setup command FTFA->FCCOB0 = EraseSector; FTFA->FCCOB1 = (address >> 16) & 0xFF; FTFA->FCCOB2 = (address >> 8) & 0xFF; FTFA->FCCOB3 = address & 0xFF; run_command(); return check_error(); } __attribute__((section(".ARM.__at_0x7300"))) IAPCode program_flash(int address, char *data, unsigned int length) { #ifdef IAPDEBUG printf("IAP: Programming flash at %x with length %d\r\n", address, length); #endif if (check_align(address)) return AlignError; IAPCode eraseCheck = verify_erased(address, length); if (eraseCheck != Success) return eraseCheck; IAPCode progResult; #ifdef USE_ProgramPhrase for (int i = 0; i < length; i+=8) { progResult = program_word(address + i, data + i); if (progResult != Success) return progResult; } #else for (int i = 0; i < length; i+=4) { progResult = program_word(address + i, data + i); if (progResult != Success) return progResult; } #endif return Success; } __attribute__((section(".ARM.__at_0x7500"))) uint32_t flash_size(void) { uint32_t retval = (SIM->FCFG2 & 0x7F000000u) >> (24-13); if (SIM->FCFG2 & (1<<23)) //Possible second flash bank retval += (SIM->FCFG2 & 0x007F0000u) >> (16-13); return retval; } __attribute__((section(".ARM.__at_0x7600"))) IAPCode program_word(int address, char *data) { #ifdef IAPDEBUG #ifdef USE_ProgramPhrase printf("IAP: Programming word at %x, %d - %d - %d - %d - %d - %d - %d - %d\r\n", address, data[0], data[1], data[2], data[3], data[4], data[5], data[6], data[7]); #else printf("IAP: Programming word at %x, %d - %d - %d - %d\r\n", address, data[0], data[1], data[2], data[3]); #endif #endif if (check_align(address)) return AlignError; #ifdef USE_ProgramPhrase FTFA->FCCOB0 = ProgramPhrase; FTFA->FCCOB1 = (address >> 16) & 0xFF; FTFA->FCCOB2 = (address >> 8) & 0xFF; FTFA->FCCOB3 = address & 0xFF; FTFA->FCCOB4 = data[3]; FTFA->FCCOB5 = data[2]; FTFA->FCCOB6 = data[1]; FTFA->FCCOB7 = data[0]; FTFA->FCCOB8 = data[7]; FTFA->FCCOB9 = data[6]; FTFA->FCCOBA = data[5]; FTFA->FCCOBB = data[4]; #else //Setup command FTFA->FCCOB0 = ProgramLongword; FTFA->FCCOB1 = (address >> 16) & 0xFF; FTFA->FCCOB2 = (address >> 8) & 0xFF; FTFA->FCCOB3 = address & 0xFF; FTFA->FCCOB4 = data[3]; FTFA->FCCOB5 = data[2]; FTFA->FCCOB6 = data[1]; FTFA->FCCOB7 = data[0]; #endif run_command(); return check_error(); } /* Clear possible flags which are set, run command, wait until done */ __attribute__((section(".ARM.__at_0x7700"))) inline void run_command(void) { //Clear possible old errors, start command, wait until done __disable_irq(); //Disable IRQs, preventing IRQ routines from trying to access flash (thanks to https://mbed.org/users/mjr/) FTFA->FSTAT = FTFA_FSTAT_FPVIOL_MASK | FTFA_FSTAT_ACCERR_MASK | FTFA_FSTAT_RDCOLERR_MASK; FTFA->FSTAT = FTFA_FSTAT_CCIF_MASK; while (!(FTFA->FSTAT & FTFA_FSTAT_CCIF_MASK)); __enable_irq(); } /* Check if no flash boundary is violated Returns true on violation */ __attribute__((section(".ARM.__at_0x7800"))) bool check_boundary(int address, unsigned int length) { int temp = (address+length - 1) / SECTOR_SIZE; address /= SECTOR_SIZE; bool retval = (address != temp); #ifdef IAPDEBUG if (retval) printf("IAP: Boundary violation\r\n"); #endif return retval; } /* Check if address is correctly aligned Returns true on violation */ __attribute__((section(".ARM.__at_0x7900"))) bool check_align(int address) { bool retval = address & 0x03; #ifdef IAPDEBUG if (retval) printf("IAP: Alignment violation\r\n"); #endif return retval; } /* Check if an area of flash memory is erased Returns error code or Success (in case of fully erased) */ __attribute__((section(".ARM.__at_0x7A00"))) IAPCode verify_erased(int address, unsigned int length) { #ifdef IAPDEBUG printf("IAP: Verify erased at %x with length %d\r\n", address, length); #endif if (check_align(address)) return AlignError; //Setup command FTFA->FCCOB0 = Read1s; FTFA->FCCOB1 = (address >> 16) & 0xFF; FTFA->FCCOB2 = (address >> 8) & 0xFF; FTFA->FCCOB3 = address & 0xFF; FTFA->FCCOB4 = (length >> 10) & 0xFF; FTFA->FCCOB5 = (length >> 2) & 0xFF; FTFA->FCCOB6 = 0; run_command(); IAPCode retval = check_error(); if (retval == RuntimeError) { #ifdef IAPDEBUG printf("IAP: Flash was not erased\r\n"); #endif return EraseError; } return retval; } /* Check if an error occured Returns error code or Success*/ __attribute__((section(".ARM.__at_0x7B00"))) IAPCode check_error(void) { if (FTFA->FSTAT & FTFA_FSTAT_FPVIOL_MASK) { #ifdef IAPDEBUG printf("IAP: Protection violation\r\n"); #endif return ProtectionError; } if (FTFA->FSTAT & FTFA_FSTAT_ACCERR_MASK) { #ifdef IAPDEBUG printf("IAP: Flash access error\r\n"); #endif return AccessError; } if (FTFA->FSTAT & FTFA_FSTAT_RDCOLERR_MASK) { #ifdef IAPDEBUG printf("IAP: Collision error\r\n"); #endif return CollisionError; } if (FTFA->FSTAT & FTFA_FSTAT_MGSTAT0_MASK) { #ifdef IAPDEBUG printf("IAP: Runtime error\r\n"); #endif return RuntimeError; } #ifdef IAPDEBUG printf("IAP: No error reported\r\n"); #endif return Success; }