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1022 1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055 1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105 1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134 1135 1136 1137 1138 1139 1140 1141 1142 1143 1144 1145 1146 1147 1148 1149 1150 1151 1152 1153 1154 1155 1156 1157 1158 1159 1160 1161 1162 1163 1164 1165 1166 1167 1168 1169 1170 | /* * Copyright (c) 2014 Wind River Systems, Inc. * Copyright (c) 2020 Nordic Semiconductor ASA. * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief Common fault handler for ARM Cortex-M * * Common fault handler for ARM Cortex-M processors. */ #include <zephyr/kernel.h> #include <kernel_internal.h> #include <inttypes.h> #include <zephyr/exc_handle.h> #include <zephyr/logging/log.h> LOG_MODULE_DECLARE(os, CONFIG_KERNEL_LOG_LEVEL); #if defined(CONFIG_PRINTK) || defined(CONFIG_LOG) #define PR_EXC(...) LOG_ERR(__VA_ARGS__) #define STORE_xFAR(reg_var, reg) uint32_t reg_var = (uint32_t)reg #else #define PR_EXC(...) #define STORE_xFAR(reg_var, reg) #endif /* CONFIG_PRINTK || CONFIG_LOG */ #if (CONFIG_FAULT_DUMP == 2) #define PR_FAULT_INFO(...) PR_EXC(__VA_ARGS__) #else #define PR_FAULT_INFO(...) #endif #if defined(CONFIG_ARM_MPU) && defined(CONFIG_CPU_HAS_NXP_MPU) #define EMN(edr) (((edr) & SYSMPU_EDR_EMN_MASK) >> SYSMPU_EDR_EMN_SHIFT) #define EACD(edr) (((edr) & SYSMPU_EDR_EACD_MASK) >> SYSMPU_EDR_EACD_SHIFT) #endif /* Exception Return (EXC_RETURN) is provided in LR upon exception entry. * It is used to perform an exception return and to detect possible state * transition upon exception. */ /* Prefix. Indicates that this is an EXC_RETURN value. * This field reads as 0b11111111. */ #define EXC_RETURN_INDICATOR_PREFIX (0xFF << 24) /* bit[0]: Exception Secure. The security domain the exception was taken to. */ #define EXC_RETURN_EXCEPTION_SECURE_Pos 0 #define EXC_RETURN_EXCEPTION_SECURE_Msk \ BIT(EXC_RETURN_EXCEPTION_SECURE_Pos) #define EXC_RETURN_EXCEPTION_SECURE_Non_Secure 0 #define EXC_RETURN_EXCEPTION_SECURE_Secure EXC_RETURN_EXCEPTION_SECURE_Msk /* bit[2]: Stack Pointer selection. */ #define EXC_RETURN_SPSEL_Pos 2 #define EXC_RETURN_SPSEL_Msk BIT(EXC_RETURN_SPSEL_Pos) #define EXC_RETURN_SPSEL_MAIN 0 #define EXC_RETURN_SPSEL_PROCESS EXC_RETURN_SPSEL_Msk /* bit[3]: Mode. Indicates the Mode that was stacked from. */ #define EXC_RETURN_MODE_Pos 3 #define EXC_RETURN_MODE_Msk BIT(EXC_RETURN_MODE_Pos) #define EXC_RETURN_MODE_HANDLER 0 #define EXC_RETURN_MODE_THREAD EXC_RETURN_MODE_Msk /* bit[4]: Stack frame type. Indicates whether the stack frame is a standard * integer only stack frame or an extended floating-point stack frame. */ #define EXC_RETURN_STACK_FRAME_TYPE_Pos 4 #define EXC_RETURN_STACK_FRAME_TYPE_Msk BIT(EXC_RETURN_STACK_FRAME_TYPE_Pos) #define EXC_RETURN_STACK_FRAME_TYPE_EXTENDED 0 #define EXC_RETURN_STACK_FRAME_TYPE_STANDARD EXC_RETURN_STACK_FRAME_TYPE_Msk /* bit[5]: Default callee register stacking. Indicates whether the default * stacking rules apply, or whether the callee registers are already on the * stack. */ #define EXC_RETURN_CALLEE_STACK_Pos 5 #define EXC_RETURN_CALLEE_STACK_Msk BIT(EXC_RETURN_CALLEE_STACK_Pos) #define EXC_RETURN_CALLEE_STACK_SKIPPED 0 #define EXC_RETURN_CALLEE_STACK_DEFAULT EXC_RETURN_CALLEE_STACK_Msk /* bit[6]: Secure or Non-secure stack. Indicates whether a Secure or * Non-secure stack is used to restore stack frame on exception return. */ #define EXC_RETURN_RETURN_STACK_Pos 6 #define EXC_RETURN_RETURN_STACK_Msk BIT(EXC_RETURN_RETURN_STACK_Pos) #define EXC_RETURN_RETURN_STACK_Non_Secure 0 #define EXC_RETURN_RETURN_STACK_Secure EXC_RETURN_RETURN_STACK_Msk /* Integrity signature for an ARMv8-M implementation */ #if defined(CONFIG_ARMV7_M_ARMV8_M_FP) #define INTEGRITY_SIGNATURE_STD 0xFEFA125BUL #define INTEGRITY_SIGNATURE_EXT 0xFEFA125AUL #else #define INTEGRITY_SIGNATURE 0xFEFA125BUL #endif /* CONFIG_ARMV7_M_ARMV8_M_FP */ /* Size (in words) of the additional state context that is pushed * to the Secure stack during a Non-Secure exception entry. */ #define ADDITIONAL_STATE_CONTEXT_WORDS 10 #if defined(CONFIG_ARMV7_M_ARMV8_M_MAINLINE) /* helpers to access memory/bus/usage faults */ #define SCB_CFSR_MEMFAULTSR \ (uint32_t)((SCB->CFSR & SCB_CFSR_MEMFAULTSR_Msk) \ >> SCB_CFSR_MEMFAULTSR_Pos) #define SCB_CFSR_BUSFAULTSR \ (uint32_t)((SCB->CFSR & SCB_CFSR_BUSFAULTSR_Msk) \ >> SCB_CFSR_BUSFAULTSR_Pos) #define SCB_CFSR_USGFAULTSR \ (uint32_t)((SCB->CFSR & SCB_CFSR_USGFAULTSR_Msk) \ >> SCB_CFSR_USGFAULTSR_Pos) #endif /* CONFIG_ARMV7_M_ARMV8_M_MAINLINE */ /** * * Dump information regarding fault (FAULT_DUMP == 1) * * Dump information regarding the fault when CONFIG_FAULT_DUMP is set to 1 * (short form). * * eg. (precise bus error escalated to hard fault): * * Fault! EXC #3 * HARD FAULT: Escalation (see below)! * MMFSR: 0x00000000, BFSR: 0x00000082, UFSR: 0x00000000 * BFAR: 0xff001234 * * * * Dump information regarding fault (FAULT_DUMP == 2) * * Dump information regarding the fault when CONFIG_FAULT_DUMP is set to 2 * (long form), and return the error code for the kernel to identify the fatal * error reason. * * eg. (precise bus error escalated to hard fault): * * ***** HARD FAULT ***** * Fault escalation (see below) * ***** BUS FAULT ***** * Precise data bus error * Address: 0xff001234 * */ #if (CONFIG_FAULT_DUMP == 1) static void fault_show(const z_arch_esf_t *esf, int fault) { PR_EXC("Fault! EXC #%d", fault); #if defined(CONFIG_ARMV7_M_ARMV8_M_MAINLINE) PR_EXC("MMFSR: 0x%x, BFSR: 0x%x, UFSR: 0x%x", SCB_CFSR_MEMFAULTSR, SCB_CFSR_BUSFAULTSR, SCB_CFSR_USGFAULTSR); #if defined(CONFIG_ARM_SECURE_FIRMWARE) PR_EXC("SFSR: 0x%x", SAU->SFSR); #endif /* CONFIG_ARM_SECURE_FIRMWARE */ #endif /* CONFIG_ARMV7_M_ARMV8_M_MAINLINE */ } #else /* For Dump level 2, detailed information is generated by the * fault handling functions for individual fault conditions, so this * function is left empty. * * For Dump level 0, no information needs to be generated. */ static void fault_show(const z_arch_esf_t *esf, int fault) { (void)esf; (void)fault; } #endif /* FAULT_DUMP == 1 */ #ifdef CONFIG_USERSPACE Z_EXC_DECLARE(z_arm_user_string_nlen); static const struct z_exc_handle exceptions[] = { Z_EXC_HANDLE(z_arm_user_string_nlen) }; #endif /* Perform an assessment whether an MPU fault shall be * treated as recoverable. * * @return true if error is recoverable, otherwise return false. */ static bool memory_fault_recoverable(z_arch_esf_t *esf, bool synchronous) { #ifdef CONFIG_USERSPACE for (int i = 0; i < ARRAY_SIZE(exceptions); i++) { /* Mask out instruction mode */ uint32_t start = (uint32_t)exceptions[i].start & ~0x1U; uint32_t end = (uint32_t)exceptions[i].end & ~0x1U; #if defined(CONFIG_NULL_POINTER_EXCEPTION_DETECTION_DWT) /* Non-synchronous exceptions (e.g. DebugMonitor) may have * allowed PC to continue to the next instruction. */ end += (synchronous) ? 0x0 : 0x4; #else ARG_UNUSED(synchronous); #endif if (esf->basic.pc >= start && esf->basic.pc < end) { esf->basic.pc = (uint32_t)(exceptions[i].fixup); return true; } } #endif return false; } #if defined(CONFIG_ARMV6_M_ARMV8_M_BASELINE) /* HardFault is used for all fault conditions on ARMv6-M. */ #elif defined(CONFIG_ARMV7_M_ARMV8_M_MAINLINE) #if defined(CONFIG_MPU_STACK_GUARD) || defined(CONFIG_USERSPACE) uint32_t z_check_thread_stack_fail(const uint32_t fault_addr, const uint32_t psp); #endif /* CONFIG_MPU_STACK_GUARD || defined(CONFIG_USERSPACE) */ /** * * @brief Dump MemManage fault information * * See z_arm_fault_dump() for example. * * @return error code to identify the fatal error reason */ static uint32_t mem_manage_fault(z_arch_esf_t *esf, int from_hard_fault, bool *recoverable) { uint32_t reason = K_ERR_ARM_MEM_GENERIC; uint32_t mmfar = -EINVAL; PR_FAULT_INFO("***** MPU FAULT *****"); if ((SCB->CFSR & SCB_CFSR_MSTKERR_Msk) != 0) { reason = K_ERR_ARM_MEM_STACKING; PR_FAULT_INFO(" Stacking error (context area might be" " not valid)"); } if ((SCB->CFSR & SCB_CFSR_MUNSTKERR_Msk) != 0) { reason = K_ERR_ARM_MEM_UNSTACKING; PR_FAULT_INFO(" Unstacking error"); } if ((SCB->CFSR & SCB_CFSR_DACCVIOL_Msk) != 0) { reason = K_ERR_ARM_MEM_DATA_ACCESS; PR_FAULT_INFO(" Data Access Violation"); /* In a fault handler, to determine the true faulting address: * 1. Read and save the MMFAR value. * 2. Read the MMARVALID bit in the MMFSR. * The MMFAR address is valid only if this bit is 1. * * Software must follow this sequence because another higher * priority exception might change the MMFAR value. */ uint32_t temp = SCB->MMFAR; if ((SCB->CFSR & SCB_CFSR_MMARVALID_Msk) != 0) { mmfar = temp; PR_EXC(" MMFAR Address: 0x%x", mmfar); if (from_hard_fault != 0) { /* clear SCB_MMAR[VALID] to reset */ SCB->CFSR &= ~SCB_CFSR_MMARVALID_Msk; } } } if ((SCB->CFSR & SCB_CFSR_IACCVIOL_Msk) != 0) { reason = K_ERR_ARM_MEM_INSTRUCTION_ACCESS; PR_FAULT_INFO(" Instruction Access Violation"); } #if defined(CONFIG_ARMV7_M_ARMV8_M_FP) if ((SCB->CFSR & SCB_CFSR_MLSPERR_Msk) != 0) { reason = K_ERR_ARM_MEM_FP_LAZY_STATE_PRESERVATION; PR_FAULT_INFO( " Floating-point lazy state preservation error"); } #endif /* CONFIG_ARMV7_M_ARMV8_M_FP */ /* When stack protection is enabled, we need to assess * if the memory violation error is a stack corruption. * * By design, being a Stacking MemManage fault is a necessary * and sufficient condition for a thread stack corruption. * [Cortex-M process stack pointer is always descending and * is never modified by code (except for the context-switch * routine), therefore, a stacking error implies the PSP has * crossed into an area beyond the thread stack.] * * Data Access Violation errors may or may not be caused by * thread stack overflows. */ if ((SCB->CFSR & SCB_CFSR_MSTKERR_Msk) || (SCB->CFSR & SCB_CFSR_DACCVIOL_Msk)) { #if defined(CONFIG_MPU_STACK_GUARD) || defined(CONFIG_USERSPACE) /* MemManage Faults are always banked between security * states. Therefore, we can safely assume the fault * originated from the same security state. * * As we only assess thread stack corruption, we only * process the error further if the stack frame is on * PSP. For always-banked MemManage Fault, this is * equivalent to inspecting the RETTOBASE flag. * * Note: * It is possible that MMFAR address is not written by the * Cortex-M core; this occurs when the stacking error is * not accompanied by a data access violation error (i.e. * when stack overflows due to the exception entry frame * stacking): z_check_thread_stack_fail() shall be able to * handle the case of 'mmfar' holding the -EINVAL value. */ if (SCB->ICSR & SCB_ICSR_RETTOBASE_Msk) { uint32_t min_stack_ptr = z_check_thread_stack_fail(mmfar, ((uint32_t) &esf[0])); if (min_stack_ptr) { /* When MemManage Stacking Error has occurred, * the stack context frame might be corrupted * but the stack pointer may have actually * descent below the allowed (thread) stack * area. We may face a problem with un-stacking * the frame, upon the exception return, if we * do not have sufficient access permissions to * read the corrupted stack frame. Therefore, * we manually force the stack pointer to the * lowest allowed position, inside the thread's * stack. * * Note: * The PSP will normally be adjusted in a tail- * chained exception performing context switch, * after aborting the corrupted thread. The * adjustment, here, is required as tail-chain * cannot always be guaranteed. * * The manual adjustment of PSP is safe, as we * will not be re-scheduling this thread again * for execution; thread stack corruption is a * fatal error and a thread that corrupted its * stack needs to be aborted. */ __set_PSP(min_stack_ptr); reason = K_ERR_STACK_CHK_FAIL; } else { __ASSERT(!(SCB->CFSR & SCB_CFSR_MSTKERR_Msk), "Stacking error not a stack fail\n"); } } #else (void)mmfar; __ASSERT(!(SCB->CFSR & SCB_CFSR_MSTKERR_Msk), "Stacking or Data Access Violation error " "without stack guard, user-mode or null-pointer detection\n"); #endif /* CONFIG_MPU_STACK_GUARD || CONFIG_USERSPACE */ } /* When we were handling this fault, we may have triggered a fp * lazy stacking Memory Manage fault. At the time of writing, this * can happen when printing. If that's true, we should clear the * pending flag in addition to the clearing the reason for the fault */ #if defined(CONFIG_ARMV7_M_ARMV8_M_FP) if ((SCB->CFSR & SCB_CFSR_MLSPERR_Msk) != 0) { SCB->SHCSR &= ~SCB_SHCSR_MEMFAULTPENDED_Msk; } #endif /* CONFIG_ARMV7_M_ARMV8_M_FP */ /* clear MMFSR sticky bits */ SCB->CFSR |= SCB_CFSR_MEMFAULTSR_Msk; /* Assess whether system shall ignore/recover from this MPU fault. */ *recoverable = memory_fault_recoverable(esf, true); return reason; } /** * * @brief Dump BusFault information * * See z_arm_fault_dump() for example. * * @return error code to identify the fatal error reason. * */ static int bus_fault(z_arch_esf_t *esf, int from_hard_fault, bool *recoverable) { uint32_t reason = K_ERR_ARM_BUS_GENERIC; PR_FAULT_INFO("***** BUS FAULT *****"); if (SCB->CFSR & SCB_CFSR_STKERR_Msk) { reason = K_ERR_ARM_BUS_STACKING; PR_FAULT_INFO(" Stacking error"); } if (SCB->CFSR & SCB_CFSR_UNSTKERR_Msk) { reason = K_ERR_ARM_BUS_UNSTACKING; PR_FAULT_INFO(" Unstacking error"); } if (SCB->CFSR & SCB_CFSR_PRECISERR_Msk) { reason = K_ERR_ARM_BUS_PRECISE_DATA_BUS; PR_FAULT_INFO(" Precise data bus error"); /* In a fault handler, to determine the true faulting address: * 1. Read and save the BFAR value. * 2. Read the BFARVALID bit in the BFSR. * The BFAR address is valid only if this bit is 1. * * Software must follow this sequence because another * higher priority exception might change the BFAR value. */ STORE_xFAR(bfar, SCB->BFAR); if ((SCB->CFSR & SCB_CFSR_BFARVALID_Msk) != 0) { PR_EXC(" BFAR Address: 0x%x", bfar); if (from_hard_fault != 0) { /* clear SCB_CFSR_BFAR[VALID] to reset */ SCB->CFSR &= ~SCB_CFSR_BFARVALID_Msk; } } } if (SCB->CFSR & SCB_CFSR_IMPRECISERR_Msk) { reason = K_ERR_ARM_BUS_IMPRECISE_DATA_BUS; PR_FAULT_INFO(" Imprecise data bus error"); } if ((SCB->CFSR & SCB_CFSR_IBUSERR_Msk) != 0) { reason = K_ERR_ARM_BUS_INSTRUCTION_BUS; PR_FAULT_INFO(" Instruction bus error"); #if !defined(CONFIG_ARMV7_M_ARMV8_M_FP) } #else } else if (SCB->CFSR & SCB_CFSR_LSPERR_Msk) { reason = K_ERR_ARM_BUS_FP_LAZY_STATE_PRESERVATION; PR_FAULT_INFO(" Floating-point lazy state preservation error"); } else { ; } #endif /* !defined(CONFIG_ARMV7_M_ARMV8_M_FP) */ #if defined(CONFIG_ARM_MPU) && defined(CONFIG_CPU_HAS_NXP_MPU) uint32_t sperr = SYSMPU->CESR & SYSMPU_CESR_SPERR_MASK; uint32_t mask = BIT(31); int i; uint32_t ear = -EINVAL; if (sperr) { for (i = 0; i < SYSMPU_EAR_COUNT; i++, mask >>= 1) { if ((sperr & mask) == 0U) { continue; } STORE_xFAR(edr, SYSMPU->SP[i].EDR); ear = SYSMPU->SP[i].EAR; PR_FAULT_INFO(" NXP MPU error, port %d", i); PR_FAULT_INFO(" Mode: %s, %s Address: 0x%x", edr & BIT(2) ? "Supervisor" : "User", edr & BIT(1) ? "Data" : "Instruction", ear); PR_FAULT_INFO( " Type: %s, Master: %d, Regions: 0x%x", edr & BIT(0) ? "Write" : "Read", EMN(edr), EACD(edr)); /* When stack protection is enabled, we need to assess * if the memory violation error is a stack corruption. * * By design, being a Stacking Bus fault is a necessary * and sufficient condition for a stack corruption. */ if (SCB->CFSR & SCB_CFSR_STKERR_Msk) { #if defined(CONFIG_MPU_STACK_GUARD) || defined(CONFIG_USERSPACE) /* Note: we can assume the fault originated * from the same security state for ARM * platforms implementing the NXP MPU * (CONFIG_CPU_HAS_NXP_MPU=y). * * As we only assess thread stack corruption, * we only process the error further, if the * stack frame is on PSP. For NXP MPU-related * Bus Faults (banked), this is equivalent to * inspecting the RETTOBASE flag. */ if (SCB->ICSR & SCB_ICSR_RETTOBASE_Msk) { uint32_t min_stack_ptr = z_check_thread_stack_fail(ear, ((uint32_t) &esf[0])); if (min_stack_ptr) { /* When BusFault Stacking Error * has occurred, the stack * context frame might be * corrupted but the stack * pointer may have actually * moved. We may face problems * with un-stacking the frame, * upon exception return, if we * do not have sufficient * permissions to read the * corrupted stack frame. * Therefore, we manually force * the stack pointer to the * lowest allowed position. * * Note: * The PSP will normally be * adjusted in a tail-chained * exception performing context * switch, after aborting the * corrupted thread. Here, the * adjustment is required as * tail-chain cannot always be * guaranteed. */ __set_PSP(min_stack_ptr); reason = K_ERR_STACK_CHK_FAIL; break; } } #else (void)ear; __ASSERT(0, "Stacking error without stack guard" "or User-mode support"); #endif /* CONFIG_MPU_STACK_GUARD || CONFIG_USERSPACE */ } } SYSMPU->CESR &= ~sperr; } #endif /* defined(CONFIG_ARM_MPU) && defined(CONFIG_CPU_HAS_NXP_MPU) */ /* clear BFSR sticky bits */ SCB->CFSR |= SCB_CFSR_BUSFAULTSR_Msk; *recoverable = memory_fault_recoverable(esf, true); return reason; } /** * * @brief Dump UsageFault information * * See z_arm_fault_dump() for example. * * @return error code to identify the fatal error reason */ static uint32_t usage_fault(const z_arch_esf_t *esf) { uint32_t reason = K_ERR_ARM_USAGE_GENERIC; PR_FAULT_INFO("***** USAGE FAULT *****"); /* bits are sticky: they stack and must be reset */ if ((SCB->CFSR & SCB_CFSR_DIVBYZERO_Msk) != 0) { reason = K_ERR_ARM_USAGE_DIV_0; PR_FAULT_INFO(" Division by zero"); } if ((SCB->CFSR & SCB_CFSR_UNALIGNED_Msk) != 0) { reason = K_ERR_ARM_USAGE_UNALIGNED_ACCESS; PR_FAULT_INFO(" Unaligned memory access"); } #if defined(CONFIG_ARMV8_M_MAINLINE) if ((SCB->CFSR & SCB_CFSR_STKOF_Msk) != 0) { reason = K_ERR_ARM_USAGE_STACK_OVERFLOW; PR_FAULT_INFO(" Stack overflow (context area not valid)"); #if defined(CONFIG_BUILTIN_STACK_GUARD) /* Stack Overflows are always reported as stack corruption * errors. Note that the built-in stack overflow mechanism * prevents the context area to be loaded on the stack upon * UsageFault exception entry. As a result, we cannot rely * on the reported faulty instruction address, to determine * the instruction that triggered the stack overflow. */ reason = K_ERR_STACK_CHK_FAIL; #endif /* CONFIG_BUILTIN_STACK_GUARD */ } #endif /* CONFIG_ARMV8_M_MAINLINE */ if ((SCB->CFSR & SCB_CFSR_NOCP_Msk) != 0) { reason = K_ERR_ARM_USAGE_NO_COPROCESSOR; PR_FAULT_INFO(" No coprocessor instructions"); } if ((SCB->CFSR & SCB_CFSR_INVPC_Msk) != 0) { reason = K_ERR_ARM_USAGE_ILLEGAL_EXC_RETURN; PR_FAULT_INFO(" Illegal load of EXC_RETURN into PC"); } if ((SCB->CFSR & SCB_CFSR_INVSTATE_Msk) != 0) { reason = K_ERR_ARM_USAGE_ILLEGAL_EPSR; PR_FAULT_INFO(" Illegal use of the EPSR"); } if ((SCB->CFSR & SCB_CFSR_UNDEFINSTR_Msk) != 0) { reason = K_ERR_ARM_USAGE_UNDEFINED_INSTRUCTION; PR_FAULT_INFO(" Attempt to execute undefined instruction"); } /* clear UFSR sticky bits */ SCB->CFSR |= SCB_CFSR_USGFAULTSR_Msk; return reason; } #if defined(CONFIG_ARM_SECURE_FIRMWARE) /** * * @brief Dump SecureFault information * * See z_arm_fault_dump() for example. * * @return error code to identify the fatal error reason */ static uint32_t secure_fault(const z_arch_esf_t *esf) { uint32_t reason = K_ERR_ARM_SECURE_GENERIC; PR_FAULT_INFO("***** SECURE FAULT *****"); STORE_xFAR(sfar, SAU->SFAR); if ((SAU->SFSR & SAU_SFSR_SFARVALID_Msk) != 0) { PR_EXC(" Address: 0x%x", sfar); } /* bits are sticky: they stack and must be reset */ if ((SAU->SFSR & SAU_SFSR_INVEP_Msk) != 0) { reason = K_ERR_ARM_SECURE_ENTRY_POINT; PR_FAULT_INFO(" Invalid entry point"); } else if ((SAU->SFSR & SAU_SFSR_INVIS_Msk) != 0) { reason = K_ERR_ARM_SECURE_INTEGRITY_SIGNATURE; PR_FAULT_INFO(" Invalid integrity signature"); } else if ((SAU->SFSR & SAU_SFSR_INVER_Msk) != 0) { reason = K_ERR_ARM_SECURE_EXCEPTION_RETURN; PR_FAULT_INFO(" Invalid exception return"); } else if ((SAU->SFSR & SAU_SFSR_AUVIOL_Msk) != 0) { reason = K_ERR_ARM_SECURE_ATTRIBUTION_UNIT; PR_FAULT_INFO(" Attribution unit violation"); } else if ((SAU->SFSR & SAU_SFSR_INVTRAN_Msk) != 0) { reason = K_ERR_ARM_SECURE_TRANSITION; PR_FAULT_INFO(" Invalid transition"); } else if ((SAU->SFSR & SAU_SFSR_LSPERR_Msk) != 0) { reason = K_ERR_ARM_SECURE_LAZY_STATE_PRESERVATION; PR_FAULT_INFO(" Lazy state preservation"); } else if ((SAU->SFSR & SAU_SFSR_LSERR_Msk) != 0) { reason = K_ERR_ARM_SECURE_LAZY_STATE_ERROR; PR_FAULT_INFO(" Lazy state error"); } /* clear SFSR sticky bits */ SAU->SFSR |= 0xFF; return reason; } #endif /* defined(CONFIG_ARM_SECURE_FIRMWARE) */ /** * * @brief Dump debug monitor exception information * * See z_arm_fault_dump() for example. * */ static void debug_monitor(z_arch_esf_t *esf, bool *recoverable) { *recoverable = false; PR_FAULT_INFO( "***** Debug monitor exception *****"); #if defined(CONFIG_NULL_POINTER_EXCEPTION_DETECTION_DWT) if (!z_arm_debug_monitor_event_error_check()) { /* By default, all debug monitor exceptions that are not * treated as errors by z_arm_debug_event_error_check(), * they are considered as recoverable errors. */ *recoverable = true; } else { *recoverable = memory_fault_recoverable(esf, false); } #endif } #else #error Unknown ARM architecture #endif /* CONFIG_ARMV6_M_ARMV8_M_BASELINE */ static inline bool z_arm_is_synchronous_svc(z_arch_esf_t *esf) { uint16_t *ret_addr = (uint16_t *)esf->basic.pc; /* SVC is a 16-bit instruction. On a synchronous SVC * escalated to Hard Fault, the return address is the * next instruction, i.e. after the SVC. */ #define _SVC_OPCODE 0xDF00 /* We are about to de-reference the program counter at the * time of fault to determine if it was a SVC * instruction. However, we don't know if the pc itself is * valid -- we could have faulted due to trying to execute a * corrupted function pointer. * * We will temporarily ignore BusFault's so a bad program * counter does not trigger ARM lockup condition. */ #if defined(CONFIG_ARMV6_M_ARMV8_M_BASELINE) && !defined(CONFIG_ARMV8_M_BASELINE) /* Note: ARMv6-M does not support CCR.BFHFNMIGN so this access * could generate a fault if the pc was invalid. */ uint16_t fault_insn = *(ret_addr - 1); #else SCB->CCR |= SCB_CCR_BFHFNMIGN_Msk; __DSB(); __ISB(); uint16_t fault_insn = *(ret_addr - 1); SCB->CCR &= ~SCB_CCR_BFHFNMIGN_Msk; __DSB(); __ISB(); #endif /* ARMV6_M_ARMV8_M_BASELINE && !ARMV8_M_BASELINE */ if (((fault_insn & 0xff00) == _SVC_OPCODE) && ((fault_insn & 0x00ff) == _SVC_CALL_RUNTIME_EXCEPT)) { return true; } #undef _SVC_OPCODE return false; } /** * * @brief Dump hard fault information * * See z_arm_fault_dump() for example. * * @return error code to identify the fatal error reason */ static uint32_t hard_fault(z_arch_esf_t *esf, bool *recoverable) { uint32_t reason = K_ERR_CPU_EXCEPTION; PR_FAULT_INFO("***** HARD FAULT *****"); #if defined(CONFIG_ARMV6_M_ARMV8_M_BASELINE) /* Workaround for #18712: * HardFault may be due to escalation, as a result of * an SVC instruction that could not be executed; this * can occur if ARCH_EXCEPT() is called by an ISR, * which executes at priority equal to the SVC handler * priority. We handle the case of Kernel OOPS and Stack * Fail here. */ if (z_arm_is_synchronous_svc(esf)) { PR_EXC("ARCH_EXCEPT with reason %x\n", esf->basic.r0); reason = esf->basic.r0; } *recoverable = memory_fault_recoverable(esf, true); #elif defined(CONFIG_ARMV7_M_ARMV8_M_MAINLINE) *recoverable = false; if ((SCB->HFSR & SCB_HFSR_VECTTBL_Msk) != 0) { PR_EXC(" Bus fault on vector table read"); } else if ((SCB->HFSR & SCB_HFSR_DEBUGEVT_Msk) != 0) { PR_EXC(" Debug event"); } else if ((SCB->HFSR & SCB_HFSR_FORCED_Msk) != 0) { PR_EXC(" Fault escalation (see below)"); if (z_arm_is_synchronous_svc(esf)) { PR_EXC("ARCH_EXCEPT with reason %x\n", esf->basic.r0); reason = esf->basic.r0; } else if ((SCB->CFSR & SCB_CFSR_MEMFAULTSR_Msk) != 0) { reason = mem_manage_fault(esf, 1, recoverable); } else if ((SCB->CFSR & SCB_CFSR_BUSFAULTSR_Msk) != 0) { reason = bus_fault(esf, 1, recoverable); } else if ((SCB->CFSR & SCB_CFSR_USGFAULTSR_Msk) != 0) { reason = usage_fault(esf); #if defined(CONFIG_ARM_SECURE_FIRMWARE) } else if (SAU->SFSR != 0) { reason = secure_fault(esf); #endif /* CONFIG_ARM_SECURE_FIRMWARE */ } else { __ASSERT(0, "Fault escalation without FSR info"); } } else { __ASSERT(0, "HardFault without HFSR info" " Shall never occur"); } #else #error Unknown ARM architecture #endif /* CONFIG_ARMV6_M_ARMV8_M_BASELINE */ return reason; } /** * * @brief Dump reserved exception information * * See z_arm_fault_dump() for example. * */ static void reserved_exception(const z_arch_esf_t *esf, int fault) { ARG_UNUSED(esf); PR_FAULT_INFO("***** %s %d) *****", fault < 16 ? "Reserved Exception (" : "Spurious interrupt (IRQ ", fault - 16); } /* Handler function for ARM fault conditions. */ static uint32_t fault_handle(z_arch_esf_t *esf, int fault, bool *recoverable) { uint32_t reason = K_ERR_CPU_EXCEPTION; *recoverable = false; switch (fault) { case 3: reason = hard_fault(esf, recoverable); break; #if defined(CONFIG_ARMV6_M_ARMV8_M_BASELINE) /* HardFault is raised for all fault conditions on ARMv6-M. */ #elif defined(CONFIG_ARMV7_M_ARMV8_M_MAINLINE) case 4: reason = mem_manage_fault(esf, 0, recoverable); break; case 5: reason = bus_fault(esf, 0, recoverable); break; case 6: reason = usage_fault(esf); break; #if defined(CONFIG_ARM_SECURE_FIRMWARE) case 7: secure_fault(esf); break; #endif /* CONFIG_ARM_SECURE_FIRMWARE */ case 12: debug_monitor(esf, recoverable); break; #else #error Unknown ARM architecture #endif /* CONFIG_ARMV6_M_ARMV8_M_BASELINE */ default: reserved_exception(esf, fault); break; } if ((*recoverable) == false) { /* Dump generic information about the fault. */ fault_show(esf, fault); } return reason; } #if defined(CONFIG_ARM_SECURE_FIRMWARE) #if (CONFIG_FAULT_DUMP == 2) /** * @brief Dump the Secure Stack information for an exception that * has occurred in Non-Secure state. * * @param secure_esf Pointer to the secure stack frame. */ static void secure_stack_dump(const z_arch_esf_t *secure_esf) { /* * In case a Non-Secure exception interrupted the Secure * execution, the Secure state has stacked the additional * state context and the top of the stack contains the * integrity signature. * * In case of a Non-Secure function call the top of the * stack contains the return address to Secure state. */ uint32_t *top_of_sec_stack = (uint32_t *)secure_esf; uint32_t sec_ret_addr; #if defined(CONFIG_ARMV7_M_ARMV8_M_FP) if ((*top_of_sec_stack == INTEGRITY_SIGNATURE_STD) || (*top_of_sec_stack == INTEGRITY_SIGNATURE_EXT)) { #else if (*top_of_sec_stack == INTEGRITY_SIGNATURE) { #endif /* CONFIG_ARMV7_M_ARMV8_M_FP */ /* Secure state interrupted by a Non-Secure exception. * The return address after the additional state * context, stacked by the Secure code upon * Non-Secure exception entry. */ top_of_sec_stack += ADDITIONAL_STATE_CONTEXT_WORDS; secure_esf = (const z_arch_esf_t *)top_of_sec_stack; sec_ret_addr = secure_esf->basic.pc; } else { /* Exception during Non-Secure function call. * The return address is located on top of stack. */ sec_ret_addr = *top_of_sec_stack; } PR_FAULT_INFO(" S instruction address: 0x%x", sec_ret_addr); } #define SECURE_STACK_DUMP(esf) secure_stack_dump(esf) #else /* We do not dump the Secure stack information for lower dump levels. */ #define SECURE_STACK_DUMP(esf) #endif /* CONFIG_FAULT_DUMP== 2 */ #endif /* CONFIG_ARM_SECURE_FIRMWARE */ /* * This internal function does the following: * * - Retrieves the exception stack frame * - Evaluates whether to report being in a nested exception * * If the ESF is not successfully retrieved, the function signals * an error by returning NULL. * * @return ESF pointer on success, otherwise return NULL */ static inline z_arch_esf_t *get_esf(uint32_t msp, uint32_t psp, uint32_t exc_return, bool *nested_exc) { bool alternative_state_exc = false; z_arch_esf_t *ptr_esf = NULL; *nested_exc = false; if ((exc_return & EXC_RETURN_INDICATOR_PREFIX) != EXC_RETURN_INDICATOR_PREFIX) { /* Invalid EXC_RETURN value. This is a fatal error. */ return NULL; } #if defined(CONFIG_ARM_SECURE_FIRMWARE) if ((exc_return & EXC_RETURN_EXCEPTION_SECURE_Secure) == 0U) { /* Secure Firmware shall only handle Secure Exceptions. * This is a fatal error. */ return NULL; } if (exc_return & EXC_RETURN_RETURN_STACK_Secure) { /* Exception entry occurred in Secure stack. */ } else { /* Exception entry occurred in Non-Secure stack. Therefore, * msp/psp point to the Secure stack, however, the actual * exception stack frame is located in the Non-Secure stack. */ alternative_state_exc = true; /* Dump the Secure stack before handling the actual fault. */ z_arch_esf_t *secure_esf; if (exc_return & EXC_RETURN_SPSEL_PROCESS) { /* Secure stack pointed by PSP */ secure_esf = (z_arch_esf_t *)psp; } else { /* Secure stack pointed by MSP */ secure_esf = (z_arch_esf_t *)msp; *nested_exc = true; } SECURE_STACK_DUMP(secure_esf); /* Handle the actual fault. * Extract the correct stack frame from the Non-Secure state * and supply it to the fault handing function. */ if (exc_return & EXC_RETURN_MODE_THREAD) { ptr_esf = (z_arch_esf_t *)__TZ_get_PSP_NS(); } else { ptr_esf = (z_arch_esf_t *)__TZ_get_MSP_NS(); } } #elif defined(CONFIG_ARM_NONSECURE_FIRMWARE) if (exc_return & EXC_RETURN_EXCEPTION_SECURE_Secure) { /* Non-Secure Firmware shall only handle Non-Secure Exceptions. * This is a fatal error. */ return NULL; } if (exc_return & EXC_RETURN_RETURN_STACK_Secure) { /* Exception entry occurred in Secure stack. * * Note that Non-Secure firmware cannot inspect the Secure * stack to determine the root cause of the fault. Fault * inspection will indicate the Non-Secure instruction * that performed the branch to the Secure domain. */ alternative_state_exc = true; PR_FAULT_INFO("Exception occurred in Secure State"); if (exc_return & EXC_RETURN_SPSEL_PROCESS) { /* Non-Secure stack frame on PSP */ ptr_esf = (z_arch_esf_t *)psp; } else { /* Non-Secure stack frame on MSP */ ptr_esf = (z_arch_esf_t *)msp; } } else { /* Exception entry occurred in Non-Secure stack. */ } #else /* The processor has a single execution state. * We verify that the Thread mode is using PSP. */ if ((exc_return & EXC_RETURN_MODE_THREAD) && (!(exc_return & EXC_RETURN_SPSEL_PROCESS))) { PR_EXC("SPSEL in thread mode does not indicate PSP"); return NULL; } #endif /* CONFIG_ARM_SECURE_FIRMWARE */ if (!alternative_state_exc) { if (exc_return & EXC_RETURN_MODE_THREAD) { /* Returning to thread mode */ ptr_esf = (z_arch_esf_t *)psp; } else { /* Returning to handler mode */ ptr_esf = (z_arch_esf_t *)msp; *nested_exc = true; } } return ptr_esf; } /** * * @brief ARM Fault handler * * This routine is called when fatal error conditions are detected by hardware * and is responsible for: * - resetting the processor fault status registers (for the case when the * error handling policy allows the system to recover from the error), * - reporting the error information, * - determining the error reason to be provided as input to the user- * provided routine, k_sys_fatal_error_handler(). * The k_sys_fatal_error_handler() is invoked once the above operations are * completed, and is responsible for implementing the error handling policy. * * The function needs, first, to determine the exception stack frame. * Note that the current security state might not be the actual * state in which the processor was executing, when the exception occurred. * The actual state may need to be determined by inspecting the EXC_RETURN * value, which is provided as argument to the Fault handler. * * If the exception occurred in the same security state, the stack frame * will be pointed to by either MSP or PSP depending on the processor * execution state when the exception occurred. MSP and PSP values are * provided as arguments to the Fault handler. * * @param msp MSP value immediately after the exception occurred * @param psp PSP value immediately after the exception occurred * @param exc_return EXC_RETURN value present in LR after exception entry. * @param callee_regs Callee-saved registers (R4-R11, PSP) * */ void z_arm_fault(uint32_t msp, uint32_t psp, uint32_t exc_return, _callee_saved_t *callee_regs) { uint32_t reason = K_ERR_CPU_EXCEPTION; int fault = SCB->ICSR & SCB_ICSR_VECTACTIVE_Msk; bool recoverable, nested_exc; z_arch_esf_t *esf; /* Create a stack-ed copy of the ESF to be used during * the fault handling process. */ z_arch_esf_t esf_copy; /* Force unlock interrupts */ arch_irq_unlock(0); /* Retrieve the Exception Stack Frame (ESF) to be supplied * as argument to the remainder of the fault handling process. */ esf = get_esf(msp, psp, exc_return, &nested_exc); __ASSERT(esf != NULL, "ESF could not be retrieved successfully. Shall never occur."); #ifdef CONFIG_DEBUG_COREDUMP z_arm_coredump_fault_sp = POINTER_TO_UINT(esf); #endif reason = fault_handle(esf, fault, &recoverable); if (recoverable) { return; } /* Copy ESF */ #if !defined(CONFIG_EXTRA_EXCEPTION_INFO) memcpy(&esf_copy, esf, sizeof(z_arch_esf_t)); ARG_UNUSED(callee_regs); #else /* the extra exception info is not present in the original esf * so we only copy the fields before those. */ memcpy(&esf_copy, esf, offsetof(z_arch_esf_t, extra_info)); esf_copy.extra_info = (struct __extra_esf_info) { .callee = callee_regs, .exc_return = exc_return, .msp = msp }; #endif /* CONFIG_EXTRA_EXCEPTION_INFO */ /* Overwrite stacked IPSR to mark a nested exception, * or a return to Thread mode. Note that this may be * required, if the retrieved ESF contents are invalid * due to, for instance, a stacking error. */ if (nested_exc) { if ((esf_copy.basic.xpsr & IPSR_ISR_Msk) == 0) { esf_copy.basic.xpsr |= IPSR_ISR_Msk; } } else { esf_copy.basic.xpsr &= ~(IPSR_ISR_Msk); } if (IS_ENABLED(CONFIG_SIMPLIFIED_EXCEPTION_CODES) && (reason >= K_ERR_ARCH_START)) { reason = K_ERR_CPU_EXCEPTION; } z_arm_fatal_error(reason, &esf_copy); } /** * * @brief Initialization of fault handling * * Turns on the desired hardware faults. * */ void z_arm_fault_init(void) { #if defined(CONFIG_ARMV6_M_ARMV8_M_BASELINE) #elif defined(CONFIG_ARMV7_M_ARMV8_M_MAINLINE) SCB->CCR |= SCB_CCR_DIV_0_TRP_Msk; #else #error Unknown ARM architecture #endif /* CONFIG_ARMV6_M_ARMV8_M_BASELINE */ #if defined(CONFIG_BUILTIN_STACK_GUARD) /* If Stack guarding via SP limit checking is enabled, disable * SP limit checking inside HardFault and NMI. This is done * in order to allow for the desired fault logging to execute * properly in all cases. * * Note that this could allow a Secure Firmware Main Stack * to descend into non-secure region during HardFault and * NMI exception entry. To prevent from this, non-secure * memory regions must be located higher than secure memory * regions. * * For Non-Secure Firmware this could allow the Non-Secure Main * Stack to attempt to descend into secure region, in which case a * Secure Hard Fault will occur and we can track the fault from there. */ SCB->CCR |= SCB_CCR_STKOFHFNMIGN_Msk; #endif /* CONFIG_BUILTIN_STACK_GUARD */ #ifdef CONFIG_TRAP_UNALIGNED_ACCESS SCB->CCR |= SCB_CCR_UNALIGN_TRP_Msk; #endif /* CONFIG_TRAP_UNALIGNED_ACCESS */ } |