232 lines
7.4 KiB
ArmAsm
232 lines
7.4 KiB
ArmAsm
/*
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* Copyright (c) 2013-2019, ARM Limited and Contributors. All rights reserved.
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*
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* SPDX-License-Identifier: BSD-3-Clause
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*/
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#include <platform_def.h>
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#include <arch.h>
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#include <common/bl_common.h>
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#include <el3_common_macros.S>
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#include <lib/pmf/pmf_asm_macros.S>
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#include <lib/runtime_instr.h>
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#include <lib/xlat_tables/xlat_mmu_helpers.h>
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.globl bl31_entrypoint
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.globl bl31_warm_entrypoint
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/* -----------------------------------------------------
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* bl31_entrypoint() is the cold boot entrypoint,
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* executed only by the primary cpu.
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* -----------------------------------------------------
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*/
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func bl31_entrypoint
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/* ---------------------------------------------------------------
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* Stash the previous bootloader arguments x0 - x3 for later use.
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* ---------------------------------------------------------------
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*/
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mov x20, x0
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mov x21, x1
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mov x22, x2
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mov x23, x3
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/* --------------------------------------------------------------------
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* If PIE is enabled, fixup the Global descriptor Table and dynamic
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* relocations
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* --------------------------------------------------------------------
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*/
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#if ENABLE_PIE
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mov_imm x0, BL31_BASE
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mov_imm x1, BL31_LIMIT
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bl fixup_gdt_reloc
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#endif /* ENABLE_PIE */
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#if !RESET_TO_BL31
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/* ---------------------------------------------------------------------
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* For !RESET_TO_BL31 systems, only the primary CPU ever reaches
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* bl31_entrypoint() during the cold boot flow, so the cold/warm boot
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* and primary/secondary CPU logic should not be executed in this case.
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*
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* Also, assume that the previous bootloader has already initialised the
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* SCTLR_EL3, including the endianness, and has initialised the memory.
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* ---------------------------------------------------------------------
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*/
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el3_entrypoint_common \
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_init_sctlr=0 \
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_warm_boot_mailbox=0 \
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_secondary_cold_boot=0 \
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_init_memory=0 \
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_init_c_runtime=1 \
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_exception_vectors=runtime_exceptions
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#else
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/* ---------------------------------------------------------------------
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* For RESET_TO_BL31 systems which have a programmable reset address,
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* bl31_entrypoint() is executed only on the cold boot path so we can
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* skip the warm boot mailbox mechanism.
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* ---------------------------------------------------------------------
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*/
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el3_entrypoint_common \
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_init_sctlr=1 \
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_warm_boot_mailbox=!PROGRAMMABLE_RESET_ADDRESS \
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_secondary_cold_boot=!COLD_BOOT_SINGLE_CPU \
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_init_memory=1 \
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_init_c_runtime=1 \
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_exception_vectors=runtime_exceptions
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/* ---------------------------------------------------------------------
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* For RESET_TO_BL31 systems, BL31 is the first bootloader to run so
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* there's no argument to relay from a previous bootloader. Zero the
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* arguments passed to the platform layer to reflect that.
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* ---------------------------------------------------------------------
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*/
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mov x20, 0
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mov x21, 0
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mov x22, 0
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mov x23, 0
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#endif /* RESET_TO_BL31 */
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/* --------------------------------------------------------------------
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* Perform BL31 setup
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* --------------------------------------------------------------------
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*/
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mov x0, x20
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mov x1, x21
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mov x2, x22
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mov x3, x23
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bl bl31_setup
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#if ENABLE_PAUTH
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/* --------------------------------------------------------------------
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* Program APIAKey_EL1 and enable pointer authentication
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* --------------------------------------------------------------------
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*/
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bl pauth_init_enable_el3
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#endif /* ENABLE_PAUTH */
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/* --------------------------------------------------------------------
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* Jump to main function
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* --------------------------------------------------------------------
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*/
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bl bl31_main
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/* --------------------------------------------------------------------
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* Clean the .data & .bss sections to main memory. This ensures
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* that any global data which was initialised by the primary CPU
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* is visible to secondary CPUs before they enable their data
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* caches and participate in coherency.
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* --------------------------------------------------------------------
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*/
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adr x0, __DATA_START__
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adr x1, __DATA_END__
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sub x1, x1, x0
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bl clean_dcache_range
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adr x0, __BSS_START__
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adr x1, __BSS_END__
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sub x1, x1, x0
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bl clean_dcache_range
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b el3_exit
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endfunc bl31_entrypoint
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/* --------------------------------------------------------------------
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* This CPU has been physically powered up. It is either resuming from
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* suspend or has simply been turned on. In both cases, call the BL31
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* warmboot entrypoint
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* --------------------------------------------------------------------
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*/
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func bl31_warm_entrypoint
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#if ENABLE_RUNTIME_INSTRUMENTATION
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/*
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* This timestamp update happens with cache off. The next
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* timestamp collection will need to do cache maintenance prior
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* to timestamp update.
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*/
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pmf_calc_timestamp_addr rt_instr_svc, RT_INSTR_EXIT_HW_LOW_PWR
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mrs x1, cntpct_el0
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str x1, [x0]
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#endif
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/*
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* On the warm boot path, most of the EL3 initialisations performed by
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* 'el3_entrypoint_common' must be skipped:
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*
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* - Only when the platform bypasses the BL1/BL31 entrypoint by
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* programming the reset address do we need to initialise SCTLR_EL3.
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* In other cases, we assume this has been taken care by the
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* entrypoint code.
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*
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* - No need to determine the type of boot, we know it is a warm boot.
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*
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* - Do not try to distinguish between primary and secondary CPUs, this
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* notion only exists for a cold boot.
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*
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* - No need to initialise the memory or the C runtime environment,
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* it has been done once and for all on the cold boot path.
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*/
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el3_entrypoint_common \
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_init_sctlr=PROGRAMMABLE_RESET_ADDRESS \
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_warm_boot_mailbox=0 \
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_secondary_cold_boot=0 \
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_init_memory=0 \
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_init_c_runtime=0 \
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_exception_vectors=runtime_exceptions
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/*
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* We're about to enable MMU and participate in PSCI state coordination.
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*
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* The PSCI implementation invokes platform routines that enable CPUs to
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* participate in coherency. On a system where CPUs are not
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* cache-coherent without appropriate platform specific programming,
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* having caches enabled until such time might lead to coherency issues
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* (resulting from stale data getting speculatively fetched, among
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* others). Therefore we keep data caches disabled even after enabling
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* the MMU for such platforms.
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*
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* On systems with hardware-assisted coherency, or on single cluster
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* platforms, such platform specific programming is not required to
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* enter coherency (as CPUs already are); and there's no reason to have
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* caches disabled either.
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*/
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#if HW_ASSISTED_COHERENCY || WARMBOOT_ENABLE_DCACHE_EARLY
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mov x0, xzr
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#else
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mov x0, #DISABLE_DCACHE
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#endif
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bl bl31_plat_enable_mmu
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#if ENABLE_PAUTH
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/* --------------------------------------------------------------------
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* Program APIAKey_EL1 and enable pointer authentication
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* --------------------------------------------------------------------
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*/
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bl pauth_init_enable_el3
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#endif /* ENABLE_PAUTH */
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bl psci_warmboot_entrypoint
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#if ENABLE_RUNTIME_INSTRUMENTATION
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pmf_calc_timestamp_addr rt_instr_svc, RT_INSTR_EXIT_PSCI
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mov x19, x0
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/*
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* Invalidate before updating timestamp to ensure previous timestamp
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* updates on the same cache line with caches disabled are properly
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* seen by the same core. Without the cache invalidate, the core might
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* write into a stale cache line.
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*/
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mov x1, #PMF_TS_SIZE
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mov x20, x30
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bl inv_dcache_range
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mov x30, x20
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mrs x0, cntpct_el0
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str x0, [x19]
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#endif
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b el3_exit
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endfunc bl31_warm_entrypoint
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