/* * Copyright (c) 2014-2018, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include /* Reset fn is needed in BL at reset vector */ #if defined(IMAGE_BL1) || defined(IMAGE_BL31) || (defined(IMAGE_BL2) && BL2_AT_EL3) /* * The reset handler common to all platforms. After a matching * cpu_ops structure entry is found, the correponding reset_handler * in the cpu_ops is invoked. * Clobbers: x0 - x19, x30 */ .globl reset_handler func reset_handler mov x19, x30 /* The plat_reset_handler can clobber x0 - x18, x30 */ bl plat_reset_handler /* Get the matching cpu_ops pointer */ bl get_cpu_ops_ptr #if ENABLE_ASSERTIONS cmp x0, #0 ASM_ASSERT(ne) #endif /* Get the cpu_ops reset handler */ ldr x2, [x0, #CPU_RESET_FUNC] mov x30, x19 cbz x2, 1f /* The cpu_ops reset handler can clobber x0 - x19, x30 */ br x2 1: ret endfunc reset_handler #endif #ifdef IMAGE_BL31 /* The power down core and cluster is needed only in BL31 */ /* * void prepare_cpu_pwr_dwn(unsigned int power_level) * * Prepare CPU power down function for all platforms. The function takes * a domain level to be powered down as its parameter. After the cpu_ops * pointer is retrieved from cpu_data, the handler for requested power * level is called. */ .globl prepare_cpu_pwr_dwn func prepare_cpu_pwr_dwn /* * If the given power level exceeds CPU_MAX_PWR_DWN_OPS, we call the * power down handler for the last power level */ mov_imm x2, (CPU_MAX_PWR_DWN_OPS - 1) cmp x0, x2 csel x2, x2, x0, hi mrs x1, tpidr_el3 ldr x0, [x1, #CPU_DATA_CPU_OPS_PTR] #if ENABLE_ASSERTIONS cmp x0, #0 ASM_ASSERT(ne) #endif /* Get the appropriate power down handler */ mov x1, #CPU_PWR_DWN_OPS add x1, x1, x2, lsl #3 ldr x1, [x0, x1] br x1 endfunc prepare_cpu_pwr_dwn /* * Initializes the cpu_ops_ptr if not already initialized * in cpu_data. This can be called without a runtime stack, but may * only be called after the MMU is enabled. * clobbers: x0 - x6, x10 */ .globl init_cpu_ops func init_cpu_ops mrs x6, tpidr_el3 ldr x0, [x6, #CPU_DATA_CPU_OPS_PTR] cbnz x0, 1f mov x10, x30 bl get_cpu_ops_ptr #if ENABLE_ASSERTIONS cmp x0, #0 ASM_ASSERT(ne) #endif str x0, [x6, #CPU_DATA_CPU_OPS_PTR]! mov x30, x10 1: ret endfunc init_cpu_ops #endif /* IMAGE_BL31 */ #if defined(IMAGE_BL31) && CRASH_REPORTING /* * The cpu specific registers which need to be reported in a crash * are reported via cpu_ops cpu_reg_dump function. After a matching * cpu_ops structure entry is found, the correponding cpu_reg_dump * in the cpu_ops is invoked. */ .globl do_cpu_reg_dump func do_cpu_reg_dump mov x16, x30 /* Get the matching cpu_ops pointer */ bl get_cpu_ops_ptr cbz x0, 1f /* Get the cpu_ops cpu_reg_dump */ ldr x2, [x0, #CPU_REG_DUMP] cbz x2, 1f blr x2 1: mov x30, x16 ret endfunc do_cpu_reg_dump #endif /* * The below function returns the cpu_ops structure matching the * midr of the core. It reads the MIDR_EL1 and finds the matching * entry in cpu_ops entries. Only the implementation and part number * are used to match the entries. * Return : * x0 - The matching cpu_ops pointer on Success * x0 - 0 on failure. * Clobbers : x0 - x5 */ .globl get_cpu_ops_ptr func get_cpu_ops_ptr /* Get the cpu_ops start and end locations */ adr x4, (__CPU_OPS_START__ + CPU_MIDR) adr x5, (__CPU_OPS_END__ + CPU_MIDR) /* Initialize the return parameter */ mov x0, #0 /* Read the MIDR_EL1 */ mrs x2, midr_el1 mov_imm x3, CPU_IMPL_PN_MASK /* Retain only the implementation and part number using mask */ and w2, w2, w3 1: /* Check if we have reached end of list */ cmp x4, x5 b.eq error_exit /* load the midr from the cpu_ops */ ldr x1, [x4], #CPU_OPS_SIZE and w1, w1, w3 /* Check if midr matches to midr of this core */ cmp w1, w2 b.ne 1b /* Subtract the increment and offset to get the cpu-ops pointer */ sub x0, x4, #(CPU_OPS_SIZE + CPU_MIDR) error_exit: ret endfunc get_cpu_ops_ptr /* * Extract CPU revision and variant, and combine them into a single numeric for * easier comparison. */ .globl cpu_get_rev_var func cpu_get_rev_var mrs x1, midr_el1 /* * Extract the variant[23:20] and revision[3:0] from MIDR, and pack them * as variant[7:4] and revision[3:0] of x0. * * First extract x1[23:16] to x0[7:0] and zero fill the rest. Then * extract x1[3:0] into x0[3:0] retaining other bits. */ ubfx x0, x1, #(MIDR_VAR_SHIFT - MIDR_REV_BITS), #(MIDR_REV_BITS + MIDR_VAR_BITS) bfxil x0, x1, #MIDR_REV_SHIFT, #MIDR_REV_BITS ret endfunc cpu_get_rev_var /* * Compare the CPU's revision-variant (x0) with a given value (x1), for errata * application purposes. If the revision-variant is less than or same as a given * value, indicates that errata applies; otherwise not. * * Shall clobber: x0-x3 */ .globl cpu_rev_var_ls func cpu_rev_var_ls mov x2, #ERRATA_APPLIES mov x3, #ERRATA_NOT_APPLIES cmp x0, x1 csel x0, x2, x3, ls ret endfunc cpu_rev_var_ls /* * Compare the CPU's revision-variant (x0) with a given value (x1), for errata * application purposes. If the revision-variant is higher than or same as a * given value, indicates that errata applies; otherwise not. * * Shall clobber: x0-x3 */ .globl cpu_rev_var_hs func cpu_rev_var_hs mov x2, #ERRATA_APPLIES mov x3, #ERRATA_NOT_APPLIES cmp x0, x1 csel x0, x2, x3, hs ret endfunc cpu_rev_var_hs #if REPORT_ERRATA /* * void print_errata_status(void); * * Function to print errata status for CPUs of its class. Must be called only: * * - with MMU and data caches are enabled; * - after cpu_ops have been initialized in per-CPU data. */ .globl print_errata_status func print_errata_status #ifdef IMAGE_BL1 /* * BL1 doesn't have per-CPU data. So retrieve the CPU operations * directly. */ stp xzr, x30, [sp, #-16]! bl get_cpu_ops_ptr ldp xzr, x30, [sp], #16 ldr x1, [x0, #CPU_ERRATA_FUNC] cbnz x1, .Lprint #else /* * Retrieve pointer to cpu_ops from per-CPU data, and further, the * errata printing function. If it's non-NULL, jump to the function in * turn. */ mrs x0, tpidr_el3 ldr x1, [x0, #CPU_DATA_CPU_OPS_PTR] ldr x0, [x1, #CPU_ERRATA_FUNC] cbz x0, .Lnoprint /* * Printing errata status requires atomically testing the printed flag. */ stp x19, x30, [sp, #-16]! mov x19, x0 /* * Load pointers to errata lock and printed flag. Call * errata_needs_reporting to check whether this CPU needs to report * errata status pertaining to its class. */ ldr x0, [x1, #CPU_ERRATA_LOCK] ldr x1, [x1, #CPU_ERRATA_PRINTED] bl errata_needs_reporting mov x1, x19 ldp x19, x30, [sp], #16 cbnz x0, .Lprint #endif .Lnoprint: ret .Lprint: /* Jump to errata reporting function for this CPU */ br x1 endfunc print_errata_status #endif /* * int check_wa_cve_2017_5715(void); * * This function returns: * - ERRATA_APPLIES when firmware mitigation is required. * - ERRATA_NOT_APPLIES when firmware mitigation is _not_ required. * - ERRATA_MISSING when firmware mitigation would be required but * is not compiled in. * * NOTE: Must be called only after cpu_ops have been initialized * in per-CPU data. */ .globl check_wa_cve_2017_5715 func check_wa_cve_2017_5715 mrs x0, tpidr_el3 #if ENABLE_ASSERTIONS cmp x0, #0 ASM_ASSERT(ne) #endif ldr x0, [x0, #CPU_DATA_CPU_OPS_PTR] ldr x0, [x0, #CPU_EXTRA1_FUNC] /* * If the reserved function pointer is NULL, this CPU * is unaffected by CVE-2017-5715 so bail out. */ cmp x0, #0 beq 1f br x0 1: mov x0, #ERRATA_NOT_APPLIES ret endfunc check_wa_cve_2017_5715