/* * Copyright (c) 2016 Intel Corporation * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include const NANO_ESF _default_esf = { 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad, 0xdeadbaad }; /** * * @brief Kernel fatal error handler * * This routine is called when a fatal error condition is detected by either * hardware or software. * * The caller is expected to always provide a usable ESF. In the event that the * fatal error does not have a hardware generated ESF, the caller should either * create its own or call _Fault instead. * * @param reason the reason that the handler was called * @param pEsf pointer to the exception stack frame * * @return This function does not return. */ FUNC_NORETURN void _NanoFatalErrorHandler(unsigned int reason, const NANO_ESF *esf) { LOG_PANIC(); #ifdef CONFIG_PRINTK switch (reason) { case _NANO_ERR_CPU_EXCEPTION: case _NANO_ERR_SPURIOUS_INT: break; case _NANO_ERR_ALLOCATION_FAIL: printk("**** Kernel Allocation Failure! ****\n"); break; case _NANO_ERR_KERNEL_OOPS: printk("***** Kernel OOPS! *****\n"); break; case _NANO_ERR_KERNEL_PANIC: printk("***** Kernel Panic! *****\n"); break; #ifdef CONFIG_STACK_SENTINEL case _NANO_ERR_STACK_CHK_FAIL: printk("***** Stack overflow *****\n"); break; #endif default: printk("**** Unknown Fatal Error %u! ****\n", reason); break; } /* Subtract 4 from EA since we added 4 earlier so that the faulting * instruction isn't retried. * * TODO: Only caller-saved registers get saved upon exception entry. * We may want to introduce a config option to save and dump all * registers, at the expense of some stack space. */ printk("Current thread ID: %p\n" "Faulting instruction: 0x%x\n" " r1: 0x%x r2: 0x%x r3: 0x%x r4: 0x%x\n" " r5: 0x%x r6: 0x%x r7: 0x%x r8: 0x%x\n" " r9: 0x%x r10: 0x%x r11: 0x%x r12: 0x%x\n" " r13: 0x%x r14: 0x%x r15: 0x%x ra: 0x%x\n" "estatus: %x\n", k_current_get(), esf->instr - 4, esf->r1, esf->r2, esf->r3, esf->r4, esf->r5, esf->r6, esf->r7, esf->r8, esf->r9, esf->r10, esf->r11, esf->r12, esf->r13, esf->r14, esf->r15, esf->ra, esf->estatus); #endif _SysFatalErrorHandler(reason, esf); } #if defined(CONFIG_EXTRA_EXCEPTION_INFO) && defined(CONFIG_PRINTK) \ && defined(ALT_CPU_HAS_EXTRA_EXCEPTION_INFO) static char *cause_str(u32_t cause_code) { switch (cause_code) { case 0: return "reset"; case 1: return "processor-only reset request"; case 2: return "interrupt"; case 3: return "trap"; case 4: return "unimplemented instruction"; case 5: return "illegal instruction"; case 6: return "misaligned data address"; case 7: return "misaligned destination address"; case 8: return "division error"; case 9: return "supervisor-only instruction address"; case 10: return "supervisor-only instruction"; case 11: return "supervisor-only data address"; case 12: return "TLB miss"; case 13: return "TLB permission violation (execute)"; case 14: return "TLB permission violation (read)"; case 15: return "TLB permission violation (write)"; case 16: return "MPU region violation (instruction)"; case 17: return "MPU region violation (data)"; case 18: return "ECC TLB error"; case 19: return "ECC fetch error (instruction)"; case 20: return "ECC register file error"; case 21: return "ECC data error"; case 22: return "ECC data cache writeback error"; case 23: return "bus instruction fetch error"; case 24: return "bus data region violation"; default: return "unknown"; } } #endif FUNC_NORETURN void _Fault(const NANO_ESF *esf) { #ifdef CONFIG_PRINTK /* Unfortunately, completely unavailable on Nios II/e cores */ #ifdef ALT_CPU_HAS_EXTRA_EXCEPTION_INFO u32_t exc_reg, badaddr_reg, eccftl; enum nios2_exception_cause cause; exc_reg = _nios2_creg_read(NIOS2_CR_EXCEPTION); /* Bit 31 indicates potentially fatal ECC error */ eccftl = (exc_reg & NIOS2_EXCEPTION_REG_ECCFTL_MASK) != 0; /* Bits 2-6 contain the cause code */ cause = (exc_reg & NIOS2_EXCEPTION_REG_CAUSE_MASK) >> NIOS2_EXCEPTION_REG_CAUSE_OFST; printk("Exception cause: %d ECCFTL: 0x%x\n", cause, eccftl); #if CONFIG_EXTRA_EXCEPTION_INFO printk("reason: %s\n", cause_str(cause)); #endif if (BIT(cause) & NIOS2_BADADDR_CAUSE_MASK) { badaddr_reg = _nios2_creg_read(NIOS2_CR_BADADDR); printk("Badaddr: 0x%x\n", badaddr_reg); } #endif /* ALT_CPU_HAS_EXTRA_EXCEPTION_INFO */ #endif /* CONFIG_PRINTK */ _NanoFatalErrorHandler(_NANO_ERR_CPU_EXCEPTION, esf); } /** * * @brief Fatal error handler * * This routine implements the corrective action to be taken when the system * detects a fatal error. * * This sample implementation attempts to abort the current thread and allow * the system to continue executing, which may permit the system to continue * functioning with degraded capabilities. * * System designers may wish to enhance or substitute this sample * implementation to take other actions, such as logging error (or debug) * information to a persistent repository and/or rebooting the system. * * @param reason the fatal error reason * @param pEsf pointer to exception stack frame * * @return N/A */ FUNC_NORETURN __weak void _SysFatalErrorHandler(unsigned int reason, const NANO_ESF *pEsf) { ARG_UNUSED(pEsf); #if !defined(CONFIG_SIMPLE_FATAL_ERROR_HANDLER) #ifdef CONFIG_STACK_SENTINEL if (reason == _NANO_ERR_STACK_CHK_FAIL) { goto hang_system; } #endif if (reason == _NANO_ERR_KERNEL_PANIC) { goto hang_system; } if (k_is_in_isr() || _is_thread_essential()) { printk("Fatal fault in %s! Spinning...\n", k_is_in_isr() ? "ISR" : "essential thread"); goto hang_system; } printk("Fatal fault in thread %p! Aborting.\n", _current); k_thread_abort(_current); hang_system: #else ARG_UNUSED(reason); #endif #ifdef ALT_CPU_HAS_DEBUG_STUB _nios2_break(); #endif for (;;) { k_cpu_idle(); } CODE_UNREACHABLE; }