/* * This file is free software: you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This file is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * See the GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program. If not, see . * * Code by Andrew Tridgell and Siddharth Bharat Purohit */ #include #include #include #include #include #include #include "hwdef/common/watchdog.h" #include "hwdef/common/stm32_util.h" #include #if AP_CRASHDUMP_ENABLED #include #endif #include #include "hal.h" #include #if CH_CFG_ST_RESOLUTION == 16 static_assert(sizeof(systime_t) == 2, "expected 16 bit systime_t"); #elif CH_CFG_ST_RESOLUTION == 32 static_assert(sizeof(systime_t) == 4, "expected 32 bit systime_t"); #endif static_assert(sizeof(systime_t) == sizeof(sysinterval_t), "expected systime_t same size as sysinterval_t"); #if defined(HAL_EXPECTED_SYSCLOCK) #ifdef STM32_SYS_CK static_assert(HAL_EXPECTED_SYSCLOCK == STM32_SYS_CK, "unexpected STM32_SYS_CK value"); #elif defined(STM32_HCLK) static_assert(HAL_EXPECTED_SYSCLOCK == STM32_HCLK, "unexpected STM32_HCLK value"); #else #error "unknown system clock" #endif #endif extern const AP_HAL::HAL& hal; extern "C" { #define bkpt() __asm volatile("BKPT #0\n") #if !AP_CRASHDUMP_ENABLED // do legacy hardfault handling void HardFault_Handler(void); void HardFault_Handler(void) { //Copy to local variables (not pointers) to allow GDB "i loc" to directly show the info //Get thread context. Contains main registers including PC and LR struct port_extctx ctx; memcpy(&ctx, (void*)__get_PSP(), sizeof(struct port_extctx)); (void)ctx; //Interrupt status register: Which interrupt have we encountered, e.g. HardFault? FaultType faultType = (FaultType)__get_IPSR(); (void)faultType; //For HardFault/BusFault this is the address that was accessed causing the error uint32_t faultAddress = SCB->BFAR; (void)faultAddress; bool forced = SCB->HFSR & SCB_HFSR_FORCED_Msk; (void)forced; uint32_t cfsr = SCB->CFSR; (void)cfsr; //Flags about hardfault / busfault //See http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dui0552a/Cihdjcfc.html for reference bool isFaultPrecise = ((SCB->CFSR >> SCB_CFSR_BUSFAULTSR_Pos) & (1 << 1) ? true : false); bool isFaultImprecise = ((SCB->CFSR >> SCB_CFSR_BUSFAULTSR_Pos) & (1 << 2) ? true : false); bool isFaultOnUnstacking = ((SCB->CFSR >> SCB_CFSR_BUSFAULTSR_Pos) & (1 << 3) ? true : false); bool isFaultOnStacking = ((SCB->CFSR >> SCB_CFSR_BUSFAULTSR_Pos) & (1 << 4) ? true : false); bool isFaultAddressValid = ((SCB->CFSR >> SCB_CFSR_BUSFAULTSR_Pos) & (1 << 7) ? true : false); (void)isFaultPrecise; (void)isFaultImprecise; (void)isFaultOnUnstacking; (void)isFaultOnStacking; (void)isFaultAddressValid; save_fault_watchdog(__LINE__, faultType, faultAddress, (uint32_t)ctx.lr_thd); #ifdef HAL_GPIO_PIN_FAULT while (true) { // forced means that another kind of unhandled fault got escalated to a hardfault if (faultType == BusFault) { fault_printf("BUSFAULT\n"); } else if (forced) { fault_printf("FORCED HARDFAULT\n"); } else { fault_printf("HARDFAULT(%d)\n", int(faultType)); } fault_printf("CSFR=0x%08x\n", cfsr); fault_printf("CUR=0x%08x\n", ch.rlist.current); if (ch.rlist.current) { fault_printf("NAME=%s\n", ch.rlist.current->name); } fault_printf("FA=0x%08x\n", faultAddress); fault_printf("PC=0x%08x\n", ctx.pc); fault_printf("LR=0x%08x\n", ctx.lr_thd); fault_printf("R0=0x%08x\n", ctx.r0); fault_printf("R1=0x%08x\n", ctx.r1); fault_printf("R2=0x%08x\n", ctx.r2); fault_printf("R3=0x%08x\n", ctx.r3); fault_printf("R12=0x%08x\n", ctx.r12); fault_printf("XPSR=0x%08x\n", ctx.xpsr); fault_printf("\n\n"); } #endif //Cause debugger to stop. Ignored if no debugger is attached while(1) {} } // For the BusFault handler to be active SCB_SHCSR_BUSFAULTENA_Msk should be set in SCB->SHCSR // ChibiOS does not do this by default void BusFault_Handler(void) __attribute__((alias("HardFault_Handler"))); void UsageFault_Handler(void); void UsageFault_Handler(void) { //Copy to local variables (not pointers) to allow GDB "i loc" to directly show the info //Get thread context. Contains main registers including PC and LR struct port_extctx ctx; memcpy(&ctx, (void*)__get_PSP(), sizeof(struct port_extctx)); (void)ctx; //Interrupt status register: Which interrupt have we encountered, e.g. HardFault? FaultType faultType = (FaultType)__get_IPSR(); (void)faultType; uint32_t faultAddress = SCB->BFAR; //Flags about hardfault / busfault //See http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dui0552a/Cihdjcfc.html for reference bool isUndefinedInstructionFault = ((SCB->CFSR >> SCB_CFSR_USGFAULTSR_Pos) & (1 << 0) ? true : false); bool isEPSRUsageFault = ((SCB->CFSR >> SCB_CFSR_USGFAULTSR_Pos) & (1 << 1) ? true : false); bool isInvalidPCFault = ((SCB->CFSR >> SCB_CFSR_USGFAULTSR_Pos) & (1 << 2) ? true : false); bool isNoCoprocessorFault = ((SCB->CFSR >> SCB_CFSR_USGFAULTSR_Pos) & (1 << 3) ? true : false); bool isUnalignedAccessFault = ((SCB->CFSR >> SCB_CFSR_USGFAULTSR_Pos) & (1 << 8) ? true : false); bool isDivideByZeroFault = ((SCB->CFSR >> SCB_CFSR_USGFAULTSR_Pos) & (1 << 9) ? true : false); (void)isUndefinedInstructionFault; (void)isEPSRUsageFault; (void)isInvalidPCFault; (void)isNoCoprocessorFault; (void)isUnalignedAccessFault; (void)isDivideByZeroFault; save_fault_watchdog(__LINE__, faultType, faultAddress, (uint32_t)ctx.lr_thd); //Cause debugger to stop. Ignored if no debugger is attached while(1) {} } void MemManage_Handler(void); void MemManage_Handler(void) { //Copy to local variables (not pointers) to allow GDB "i loc" to directly show the info //Get thread context. Contains main registers including PC and LR struct port_extctx ctx; memcpy(&ctx, (void*)__get_PSP(), sizeof(struct port_extctx)); (void)ctx; //Interrupt status register: Which interrupt have we encountered, e.g. HardFault? FaultType faultType = (FaultType)__get_IPSR(); (void)faultType; //For HardFault/BusFault this is the address that was accessed causing the error uint32_t faultAddress = SCB->MMFAR; (void)faultAddress; //Flags about hardfault / busfault //See http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dui0552a/Cihdjcfc.html for reference bool isInstructionAccessViolation = ((SCB->CFSR >> SCB_CFSR_MEMFAULTSR_Pos) & (1 << 0) ? true : false); bool isDataAccessViolation = ((SCB->CFSR >> SCB_CFSR_MEMFAULTSR_Pos) & (1 << 1) ? true : false); bool isExceptionUnstackingFault = ((SCB->CFSR >> SCB_CFSR_MEMFAULTSR_Pos) & (1 << 3) ? true : false); bool isExceptionStackingFault = ((SCB->CFSR >> SCB_CFSR_MEMFAULTSR_Pos) & (1 << 4) ? true : false); bool isFaultAddressValid = ((SCB->CFSR >> SCB_CFSR_MEMFAULTSR_Pos) & (1 << 7) ? true : false); (void)isInstructionAccessViolation; (void)isDataAccessViolation; (void)isExceptionUnstackingFault; (void)isExceptionStackingFault; (void)isFaultAddressValid; save_fault_watchdog(__LINE__, faultType, faultAddress, (uint32_t)ctx.lr_thd); while(1) {} } #else // Handle via Crash Catcher extern void HardFault_Handler(void); void BusFault_Handler(void); void BusFault_Handler(void) { HardFault_Handler(); } void UsageFault_Handler(void); void UsageFault_Handler(void) { HardFault_Handler(); } void MemManage_Handler(void); void MemManage_Handler(void) { HardFault_Handler(); } #endif /* save watchdog data for a hard fault */ void save_fault_watchdog(uint16_t line, FaultType fault_type, uint32_t fault_addr, uint32_t lr) { #ifndef HAL_BOOTLOADER_BUILD bool using_watchdog = AP_BoardConfig::watchdog_enabled(); if (using_watchdog) { AP_HAL::Util::PersistentData &pd = hal.util->persistent_data; if (pd.fault_type == 0) { // don't overwrite earlier fault pd.fault_line = line; pd.fault_type = fault_type; pd.fault_addr = fault_addr; thread_t *tp = chThdGetSelfX(); if (tp) { pd.fault_thd_prio = tp->hdr.pqueue.prio; // get first 4 bytes of the name, but only of first fault if (tp->name && pd.thread_name4[0] == 0) { strncpy_noterm(pd.thread_name4, tp->name, 4); } } pd.fault_icsr = SCB->ICSR; pd.fault_lr = lr; } stm32_watchdog_save((uint32_t *)&hal.util->persistent_data, (sizeof(hal.util->persistent_data)+3)/4); } #endif } void *__dso_handle; void __cxa_pure_virtual(void); void __cxa_pure_virtual() { while (1); } //TODO: Handle properly, maybe generate a traceback void NMI_Handler(void); void NMI_Handler(void) { while (1); } } namespace AP_HAL { void init() { } void panic(const char *errormsg, ...) { #if !defined(HAL_BOOTLOADER_BUILD) && !APM_BUILD_TYPE(APM_BUILD_iofirmware) INTERNAL_ERROR(AP_InternalError::error_t::panic); va_list ap; va_start(ap, errormsg); vprintf(errormsg, ap); va_end(ap); hal.scheduler->delay_microseconds(10000); while (1) { va_start(ap, errormsg); vprintf(errormsg, ap); va_end(ap); hal.scheduler->delay(500); } #else // we don't support variable args in bootlaoder chSysHalt(errormsg); // we will never get here, this just to silence a warning while (1) {} #endif } __FASTRAMFUNC__ uint32_t micros() { #if CH_CFG_ST_RESOLUTION == 32 && CH_CFG_ST_FREQUENCY==1000000U // special case optimisation for 32 bit timers return st_lld_get_counter(); #else return hrt_micros32(); #endif } uint16_t micros16() { #if CH_CFG_ST_RESOLUTION == 32 && CH_CFG_ST_FREQUENCY==1000000U return st_lld_get_counter() & 0xFFFF; #elif CH_CFG_ST_RESOLUTION == 16 && CH_CFG_ST_FREQUENCY==1000000U return st_lld_get_counter(); #else return hrt_micros32() & 0xFFFF; #endif } __FASTRAMFUNC__ uint32_t millis() { return hrt_millis32(); } __FASTRAMFUNC__ uint16_t millis16() { return hrt_millis32() & 0xFFFF; } __FASTRAMFUNC__ uint64_t micros64() { return hrt_micros64(); } __FASTRAMFUNC__ uint64_t millis64() { return hrt_micros64() / 1000U; } __FASTRAMFUNC__ uint32_t native_micros() { return micros(); } __FASTRAMFUNC__ uint32_t native_millis() { return millis(); } __FASTRAMFUNC__ uint16_t native_millis16() { return millis16(); } __FASTRAMFUNC__ uint64_t native_micros64() { return micros64(); } __FASTRAMFUNC__ uint64_t native_millis64() { return millis64(); } } // namespace AP_HAL