/* * Copyright (c) 2023-2024, Arm Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include "cpu_errata_info.h" #include #include #include #include #include #include /* * Global pointer that points to the specific * structure based on the MIDR part number */ struct em_cpu_list *cpu_ptr; /* Structure array that holds CPU specific errata information */ struct em_cpu_list cpu_list[] = { #if CORTEX_A78_H_INC { .cpu_partnumber = CORTEX_A78_MIDR, .cpu_errata_list = { [0] = {2712571, 0x00, 0x12}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* CORTEX_A78_H_INC */ #if CORTEX_A78_AE_H_INC { .cpu_partnumber = CORTEX_A78_AE_MIDR, .cpu_errata_list = { [0] = {2712574, 0x00, 0x02}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* CORTEX_A78_AE_H_INC */ #if CORTEX_A78C_H_INC { .cpu_partnumber = CORTEX_A78C_MIDR, .cpu_errata_list = { [0] = {2712575, 0x01, 0x02}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* CORTEX_A78C_H_INC */ #if NEOVERSE_V1_H_INC { .cpu_partnumber = NEOVERSE_V1_MIDR, .cpu_errata_list = { [0] = {2701953, 0x00, 0x11}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* NEOVERSE_V1_H_INC */ #if CORTEX_A710_H_INC { .cpu_partnumber = CORTEX_A710_MIDR, .cpu_errata_list = { [0] = {2701952, 0x00, 0x21}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* CORTEX_A710_H_INC */ #if NEOVERSE_N2_H_INC { .cpu_partnumber = NEOVERSE_N2_MIDR, .cpu_errata_list = { [0] = {2728475, 0x00, 0x02}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* NEOVERSE_N2_H_INC */ #if CORTEX_X2_H_INC { .cpu_partnumber = CORTEX_X2_MIDR, .cpu_errata_list = { [0] = {2701952, 0x00, 0x21}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* CORTEX_X2_H_INC */ #if NEOVERSE_V2_H_INC { .cpu_partnumber = NEOVERSE_V2_MIDR, .cpu_errata_list = { [0] = {2719103, 0x00, 0x01}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* NEOVERSE_V2_H_INC */ #if CORTEX_X3_H_INC { .cpu_partnumber = CORTEX_X3_MIDR, .cpu_errata_list = { [0] = {2701951, 0x00, 0x11}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* CORTEX_X3_H_INC */ #if CORTEX_X4_H_INC { .cpu_partnumber = CORTEX_X4_MIDR, .cpu_errata_list = { [0] = {2701112, 0x00, 0x00}, [1 ... ERRATA_LIST_END] = UNDEF_ERRATA, } }, #endif /* CORTEX_X4_H_INC */ }; #if ERRATA_NON_ARM_INTERCONNECT /* Check if the errata is enabled for non-arm interconnect */ static int32_t non_arm_interconnect_errata(uint32_t errata_id, long rev_var) { int32_t ret_val = EM_UNKNOWN_ERRATUM; /* Determine the number of cpu listed in the cpu list */ uint8_t size_cpulist = ARRAY_SIZE(cpu_list); /* Read the midr reg to extract cpu, revision and variant info */ uint32_t midr_val = read_midr(); for (uint8_t i = 0U; i < size_cpulist; i++) { cpu_ptr = &cpu_list[i]; /* * If the cpu partnumber in the cpu list, matches the midr * part number, check to see if the errata ID matches */ if (EXTRACT_PARTNUM(midr_val) == EXTRACT_PARTNUM(cpu_ptr->cpu_partnumber)) { struct em_cpu *ptr = NULL; for (int j = 0; j < MAX_PLAT_CPU_ERRATA_ENTRIES; j++) { ptr = &cpu_ptr->cpu_errata_list[j]; assert(ptr != NULL); if (errata_id == ptr->em_errata_id) { if (RXPX_RANGE(rev_var, ptr->em_rxpx_lo, ptr->em_rxpx_hi)) { ret_val = EM_AFFECTED; break; } ret_val = EM_NOT_AFFECTED; break; } } break; } } return ret_val; } #endif /* Function to check if the errata exists for the specific CPU and rxpx */ int32_t verify_errata_implemented(uint32_t errata_id, uint32_t forward_flag) { int32_t ret_val; struct cpu_ops *cpu_ops; struct erratum_entry *entry, *end; long rev_var; ret_val = EM_UNKNOWN_ERRATUM; rev_var = cpu_get_rev_var(); #if ERRATA_NON_ARM_INTERCONNECT ret_val = non_arm_interconnect_errata(errata_id, rev_var); if (ret_val != EM_UNKNOWN_ERRATUM) { return ret_val; } #endif cpu_ops = get_cpu_ops_ptr(); assert(cpu_ops != NULL); entry = cpu_ops->errata_list_start; assert(entry != NULL); end = cpu_ops->errata_list_end; assert(end != NULL); end--; /* point to the last erratum entry of the queried cpu */ while ((entry <= end) && (ret_val == EM_UNKNOWN_ERRATUM)) { if (entry->id == errata_id) { if (entry->check_func(rev_var)) { if (entry->chosen) return EM_HIGHER_EL_MITIGATION; else return EM_AFFECTED; } return EM_NOT_AFFECTED; } entry += 1; } return ret_val; } /* Predicate indicating that a function id is part of EM_ABI */ bool is_errata_fid(uint32_t smc_fid) { return ((smc_fid == ARM_EM_VERSION) || (smc_fid == ARM_EM_FEATURES) || (smc_fid == ARM_EM_CPU_ERRATUM_FEATURES)); } bool validate_spsr_mode(void) { /* In AArch64, if the caller is EL1, return true */ #if __aarch64__ if (GET_EL(read_spsr_el3()) == MODE_EL1) { return true; } return false; #else /* In AArch32, if in system/svc mode, return true */ uint8_t read_el_state = GET_M32(read_spsr()); if ((read_el_state == (MODE32_svc)) || (read_el_state == MODE32_sys)) { return true; } return false; #endif /* __aarch64__ */ } uintptr_t errata_abi_smc_handler(uint32_t smc_fid, u_register_t x1, u_register_t x2, u_register_t x3, u_register_t x4, void *cookie, void *handle, u_register_t flags) { int32_t ret_id = EM_UNKNOWN_ERRATUM; switch (smc_fid) { case ARM_EM_VERSION: SMC_RET1(handle, MAKE_SMCCC_VERSION( EM_VERSION_MAJOR, EM_VERSION_MINOR )); break; /* unreachable */ case ARM_EM_FEATURES: if (is_errata_fid((uint32_t)x1)) { SMC_RET1(handle, EM_SUCCESS); } SMC_RET1(handle, EM_NOT_SUPPORTED); break; /* unreachable */ case ARM_EM_CPU_ERRATUM_FEATURES: /* * If the forward flag is greater than zero and the calling EL * is EL1 in AArch64 or in system mode or svc mode in case of AArch32, * return Invalid Parameters. */ if (((uint32_t)x2 != 0) && (validate_spsr_mode())) { SMC_RET1(handle, EM_INVALID_PARAMETERS); } ret_id = verify_errata_implemented((uint32_t)x1, (uint32_t)x2); SMC_RET1(handle, ret_id); break; /* unreachable */ default: { WARN("Unimplemented Errata ABI Service Call: 0x%x\n", smc_fid); SMC_RET1(handle, EM_UNKNOWN_ERRATUM); break; /* unreachable */ } } }