bl31/aarch64/bl31_entrypoint.S - filogic/atf - Gitiles

 /*
  * Copyright (c) 2013-2018, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch.h>
 #include <bl_common.h>
 #include <el3_common_macros.S>
 #include <pmf_asm_macros.S>
 #include <runtime_instr.h>
 #include <xlat_mmu_helpers.h>

 	.globl	bl31_entrypoint
 	.globl	bl31_warm_entrypoint

 	/* -----------------------------------------------------
 	 * bl31_entrypoint() is the cold boot entrypoint,
 	 * executed only by the primary cpu.
 	 * -----------------------------------------------------
 	 */

 func bl31_entrypoint
 #if !RESET_TO_BL31
 	/* ---------------------------------------------------------------
 	 * Stash the previous bootloader arguments x0 - x3 for later use.
 	 * ---------------------------------------------------------------
 	 */
 	mov	x20, x0
 	mov	x21, x1
 	mov	x22, x2
 	mov	x23, x3

 	/* ---------------------------------------------------------------------
 	 * For !RESET_TO_BL31 systems, only the primary CPU ever reaches
 	 * bl31_entrypoint() during the cold boot flow, so the cold/warm boot
 	 * and primary/secondary CPU logic should not be executed in this case.
 	 *
 	 * Also, assume that the previous bootloader has already initialised the
 	 * SCTLR_EL3, including the endianness, and has initialised the memory.
 	 * ---------------------------------------------------------------------
 	 */
 	el3_entrypoint_common					\
 		_init_sctlr=0					\
 		_warm_boot_mailbox=0				\
 		_secondary_cold_boot=0				\
 		_init_memory=0					\
 		_init_c_runtime=1				\
 		_exception_vectors=runtime_exceptions
 #else
 	/* ---------------------------------------------------------------------
 	 * For RESET_TO_BL31 systems which have a programmable reset address,
 	 * bl31_entrypoint() is executed only on the cold boot path so we can
 	 * skip the warm boot mailbox mechanism.
 	 * ---------------------------------------------------------------------
 	 */
 	el3_entrypoint_common					\
 		_init_sctlr=1					\
 		_warm_boot_mailbox=!PROGRAMMABLE_RESET_ADDRESS	\
 		_secondary_cold_boot=!COLD_BOOT_SINGLE_CPU	\
 		_init_memory=1					\
 		_init_c_runtime=1				\
 		_exception_vectors=runtime_exceptions

 	/* ---------------------------------------------------------------------
 	 * For RESET_TO_BL31 systems, BL31 is the first bootloader to run so
 	 * there's no argument to relay from a previous bootloader. Zero the
 	 * arguments passed to the platform layer to reflect that.
 	 * ---------------------------------------------------------------------
 	 */
 	mov	x20, 0
 	mov	x21, 0
 	mov	x22, 0
 	mov	x23, 0
 #endif /* RESET_TO_BL31 */
 	/* ---------------------------------------------
 	 * Perform platform specific early arch. setup
 	 * ---------------------------------------------
 	 */
 	mov	x0, x20
 	mov	x1, x21
 	mov	x2, x22
 	mov	x3, x23
 	bl	bl31_early_platform_setup2
 	bl	bl31_plat_arch_setup

 	/* ---------------------------------------------
 	 * Jump to main function.
 	 * ---------------------------------------------
 	 */
 	bl	bl31_main

 	/* -------------------------------------------------------------
 	 * Clean the .data & .bss sections to main memory. This ensures
 	 * that any global data which was initialised by the primary CPU
 	 * is visible to secondary CPUs before they enable their data
 	 * caches and participate in coherency.
 	 * -------------------------------------------------------------
 	 */
 	adr	x0, __DATA_START__
 	adr	x1, __DATA_END__
 	sub	x1, x1, x0
 	bl	clean_dcache_range

 	adr	x0, __BSS_START__
 	adr	x1, __BSS_END__
 	sub	x1, x1, x0
 	bl	clean_dcache_range

 	b	el3_exit
 endfunc bl31_entrypoint

 	/* --------------------------------------------------------------------
 	 * This CPU has been physically powered up. It is either resuming from
 	 * suspend or has simply been turned on. In both cases, call the BL31
 	 * warmboot entrypoint
 	 * --------------------------------------------------------------------
 	 */
 func bl31_warm_entrypoint
 #if ENABLE_RUNTIME_INSTRUMENTATION

 	/*
 	 * This timestamp update happens with cache off.  The next
 	 * timestamp collection will need to do cache maintenance prior
 	 * to timestamp update.
 	 */
 	pmf_calc_timestamp_addr rt_instr_svc RT_INSTR_EXIT_HW_LOW_PWR
 	mrs	x1, cntpct_el0
 	str	x1, [x0]
 #endif

 	/*
 	 * On the warm boot path, most of the EL3 initialisations performed by
 	 * 'el3_entrypoint_common' must be skipped:
 	 *
 	 *  - Only when the platform bypasses the BL1/BL31 entrypoint by
 	 *    programming the reset address do we need to initialise SCTLR_EL3.
 	 *    In other cases, we assume this has been taken care by the
 	 *    entrypoint code.
 	 *
 	 *  - No need to determine the type of boot, we know it is a warm boot.
 	 *
 	 *  - Do not try to distinguish between primary and secondary CPUs, this
 	 *    notion only exists for a cold boot.
 	 *
 	 *  - No need to initialise the memory or the C runtime environment,
 	 *    it has been done once and for all on the cold boot path.
 	 */
 	el3_entrypoint_common					\
 		_init_sctlr=PROGRAMMABLE_RESET_ADDRESS		\
 		_warm_boot_mailbox=0				\
 		_secondary_cold_boot=0				\
 		_init_memory=0					\
 		_init_c_runtime=0				\
 		_exception_vectors=runtime_exceptions

 	/*
 	 * We're about to enable MMU and participate in PSCI state coordination.
 	 *
 	 * The PSCI implementation invokes platform routines that enable CPUs to
 	 * participate in coherency. On a system where CPUs are not
 	 * cache-coherent without appropriate platform specific programming,
 	 * having caches enabled until such time might lead to coherency issues
 	 * (resulting from stale data getting speculatively fetched, among
 	 * others). Therefore we keep data caches disabled even after enabling
 	 * the MMU for such platforms.
 	 *
 	 * On systems with hardware-assisted coherency, or on single cluster
 	 * platforms, such platform specific programming is not required to
 	 * enter coherency (as CPUs already are); and there's no reason to have
 	 * caches disabled either.
 	 */
 	mov	x0, #DISABLE_DCACHE
 	bl	bl31_plat_enable_mmu

 #if HW_ASSISTED_COHERENCY || WARMBOOT_ENABLE_DCACHE_EARLY
 	mrs	x0, sctlr_el3
 	orr	x0, x0, #SCTLR_C_BIT
 	msr	sctlr_el3, x0
 	isb
 #endif

 	bl	psci_warmboot_entrypoint

 #if ENABLE_RUNTIME_INSTRUMENTATION
 	pmf_calc_timestamp_addr rt_instr_svc RT_INSTR_EXIT_PSCI
 	mov	x19, x0

 	/*
 	 * Invalidate before updating timestamp to ensure previous timestamp
 	 * updates on the same cache line with caches disabled are properly
 	 * seen by the same core. Without the cache invalidate, the core might
 	 * write into a stale cache line.
 	 */
 	mov	x1, #PMF_TS_SIZE
 	mov	x20, x30
 	bl	inv_dcache_range
 	mov	x30, x20

 	mrs	x0, cntpct_el0
 	str	x0, [x19]
 #endif
 	b	el3_exit
 endfunc bl31_warm_entrypoint
	/*
	* Copyright (c) 2013-2018, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch.h>
	#include <bl_common.h>
	#include <el3_common_macros.S>
	#include <pmf_asm_macros.S>
	#include <runtime_instr.h>
	#include <xlat_mmu_helpers.h>

	.globl bl31_entrypoint
	.globl bl31_warm_entrypoint

	/* -----------------------------------------------------
	* bl31_entrypoint() is the cold boot entrypoint,
	* executed only by the primary cpu.
	* -----------------------------------------------------
	*/

	func bl31_entrypoint
	#if !RESET_TO_BL31
	/* ---------------------------------------------------------------
	* Stash the previous bootloader arguments x0 - x3 for later use.
	* ---------------------------------------------------------------
	*/
	mov x20, x0
	mov x21, x1
	mov x22, x2
	mov x23, x3

	/* ---------------------------------------------------------------------
	* For !RESET_TO_BL31 systems, only the primary CPU ever reaches
	* bl31_entrypoint() during the cold boot flow, so the cold/warm boot
	* and primary/secondary CPU logic should not be executed in this case.
	*
	* Also, assume that the previous bootloader has already initialised the
	* SCTLR_EL3, including the endianness, and has initialised the memory.
	* ---------------------------------------------------------------------
	*/
	el3_entrypoint_common \
	_init_sctlr=0 \
	_warm_boot_mailbox=0 \
	_secondary_cold_boot=0 \
	_init_memory=0 \
	_init_c_runtime=1 \
	_exception_vectors=runtime_exceptions
	#else
	/* ---------------------------------------------------------------------
	* For RESET_TO_BL31 systems which have a programmable reset address,
	* bl31_entrypoint() is executed only on the cold boot path so we can
	* skip the warm boot mailbox mechanism.
	* ---------------------------------------------------------------------
	*/
	el3_entrypoint_common \
	_init_sctlr=1 \
	_warm_boot_mailbox=!PROGRAMMABLE_RESET_ADDRESS \
	_secondary_cold_boot=!COLD_BOOT_SINGLE_CPU \
	_init_memory=1 \
	_init_c_runtime=1 \
	_exception_vectors=runtime_exceptions

	/* ---------------------------------------------------------------------
	* For RESET_TO_BL31 systems, BL31 is the first bootloader to run so
	* there's no argument to relay from a previous bootloader. Zero the
	* arguments passed to the platform layer to reflect that.
	* ---------------------------------------------------------------------
	*/
	mov x20, 0
	mov x21, 0
	mov x22, 0
	mov x23, 0
	#endif /* RESET_TO_BL31 */
	/* ---------------------------------------------
	* Perform platform specific early arch. setup
	* ---------------------------------------------
	*/
	mov x0, x20
	mov x1, x21
	mov x2, x22
	mov x3, x23
	bl bl31_early_platform_setup2
	bl bl31_plat_arch_setup

	/* ---------------------------------------------
	* Jump to main function.
	* ---------------------------------------------
	*/
	bl bl31_main

	/* -------------------------------------------------------------
	* Clean the .data & .bss sections to main memory. This ensures
	* that any global data which was initialised by the primary CPU
	* is visible to secondary CPUs before they enable their data
	* caches and participate in coherency.
	* -------------------------------------------------------------
	*/
	adr x0, __DATA_START__
	adr x1, __DATA_END__
	sub x1, x1, x0
	bl clean_dcache_range

	adr x0, __BSS_START__
	adr x1, __BSS_END__
	sub x1, x1, x0
	bl clean_dcache_range

	b el3_exit
	endfunc bl31_entrypoint

	/* --------------------------------------------------------------------
	* This CPU has been physically powered up. It is either resuming from
	* suspend or has simply been turned on. In both cases, call the BL31
	* warmboot entrypoint
	* --------------------------------------------------------------------
	*/
	func bl31_warm_entrypoint
	#if ENABLE_RUNTIME_INSTRUMENTATION

	/*
	* This timestamp update happens with cache off. The next
	* timestamp collection will need to do cache maintenance prior
	* to timestamp update.
	*/
	pmf_calc_timestamp_addr rt_instr_svc RT_INSTR_EXIT_HW_LOW_PWR
	mrs x1, cntpct_el0
	str x1, [x0]
	#endif

	/*
	* On the warm boot path, most of the EL3 initialisations performed by
	* 'el3_entrypoint_common' must be skipped:
	*
	* - Only when the platform bypasses the BL1/BL31 entrypoint by
	* programming the reset address do we need to initialise SCTLR_EL3.
	* In other cases, we assume this has been taken care by the
	* entrypoint code.
	*
	* - No need to determine the type of boot, we know it is a warm boot.
	*
	* - Do not try to distinguish between primary and secondary CPUs, this
	* notion only exists for a cold boot.
	*
	* - No need to initialise the memory or the C runtime environment,
	* it has been done once and for all on the cold boot path.
	*/
	el3_entrypoint_common \
	_init_sctlr=PROGRAMMABLE_RESET_ADDRESS \
	_warm_boot_mailbox=0 \
	_secondary_cold_boot=0 \
	_init_memory=0 \
	_init_c_runtime=0 \
	_exception_vectors=runtime_exceptions

	/*
	* We're about to enable MMU and participate in PSCI state coordination.
	*
	* The PSCI implementation invokes platform routines that enable CPUs to
	* participate in coherency. On a system where CPUs are not
	* cache-coherent without appropriate platform specific programming,
	* having caches enabled until such time might lead to coherency issues
	* (resulting from stale data getting speculatively fetched, among
	* others). Therefore we keep data caches disabled even after enabling
	* the MMU for such platforms.
	*
	* On systems with hardware-assisted coherency, or on single cluster
	* platforms, such platform specific programming is not required to
	* enter coherency (as CPUs already are); and there's no reason to have
	* caches disabled either.
	*/
	mov x0, #DISABLE_DCACHE
	bl bl31_plat_enable_mmu

	#if HW_ASSISTED_COHERENCY \|\| WARMBOOT_ENABLE_DCACHE_EARLY
	mrs x0, sctlr_el3
	orr x0, x0, #SCTLR_C_BIT
	msr sctlr_el3, x0
	isb
	#endif

	bl psci_warmboot_entrypoint

	#if ENABLE_RUNTIME_INSTRUMENTATION
	pmf_calc_timestamp_addr rt_instr_svc RT_INSTR_EXIT_PSCI
	mov x19, x0

	/*
	* Invalidate before updating timestamp to ensure previous timestamp
	* updates on the same cache line with caches disabled are properly
	* seen by the same core. Without the cache invalidate, the core might
	* write into a stale cache line.
	*/
	mov x1, #PMF_TS_SIZE
	mov x20, x30
	bl inv_dcache_range
	mov x30, x20

	mrs x0, cntpct_el0
	str x0, [x19]
	#endif
	b el3_exit
	endfunc bl31_warm_entrypoint