include/arch/aarch64/el3_common_macros.S - filogic/atf - Gitiles

 /*
  * Copyright (c) 2015-2023, Arm Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #ifndef EL3_COMMON_MACROS_S
 #define EL3_COMMON_MACROS_S

 #include <arch.h>
 #include <asm_macros.S>
 #include <assert_macros.S>
 #include <context.h>
 #include <lib/xlat_tables/xlat_tables_defs.h>

 	/*
 	 * Helper macro to initialise EL3 registers we care about.
 	 */
 	.macro el3_arch_init_common
 	/* ---------------------------------------------------------------------
 	 * SCTLR_EL3 has already been initialised - read current value before
 	 * modifying.
 	 *
 	 * SCTLR_EL3.I: Enable the instruction cache.
 	 *
 	 * SCTLR_EL3.SA: Enable Stack Alignment check. A SP alignment fault
 	 *  exception is generated if a load or store instruction executed at
 	 *  EL3 uses the SP as the base address and the SP is not aligned to a
 	 *  16-byte boundary.
 	 *
 	 * SCTLR_EL3.A: Enable Alignment fault checking. All instructions that
 	 *  load or store one or more registers have an alignment check that the
 	 *  address being accessed is aligned to the size of the data element(s)
 	 *  being accessed.
 	 * ---------------------------------------------------------------------
 	 */
 	mov	x1, #(SCTLR_I_BIT | SCTLR_A_BIT | SCTLR_SA_BIT)
 	mrs	x0, sctlr_el3
 	orr	x0, x0, x1
 	msr	sctlr_el3, x0
 	isb

 #ifdef IMAGE_BL31
 	/* ---------------------------------------------------------------------
 	 * Initialise the per-cpu cache pointer to the CPU.
 	 * This is done early to enable crash reporting to have access to crash
 	 * stack. Since crash reporting depends on cpu_data to report the
 	 * unhandled exception, not doing so can lead to recursive exceptions
 	 * due to a NULL TPIDR_EL3.
 	 * ---------------------------------------------------------------------
 	 */
 	bl	init_cpu_data_ptr
 #endif /* IMAGE_BL31 */

 	/* ---------------------------------------------------------------------
 	 * Initialise SCR_EL3, setting all fields rather than relying on hw.
 	 * All fields are architecturally UNKNOWN on reset. The following fields
 	 * do not change during the TF lifetime. The remaining fields are set to
 	 * zero here but are updated ahead of transitioning to a lower EL in the
 	 * function cm_init_context_common().
 	 *
 	 * SCR_EL3.SIF: Set to one to disable instruction fetches from
 	 *  Non-secure memory.
 	 *
 	 * SCR_EL3.EA: Set to one to route External Aborts and SError Interrupts
 	 *  to EL3 when executing at any EL.
 	 * ---------------------------------------------------------------------
 	 */
 	mov_imm	x0, (SCR_RESET_VAL | SCR_EA_BIT | SCR_SIF_BIT)
 	msr	scr_el3, x0

 	/* ---------------------------------------------------------------------
 	 * Initialise MDCR_EL3, setting all fields rather than relying on hw.
 	 * Some fields are architecturally UNKNOWN on reset.
 	 *
 	 * MDCR_EL3.SDD: Set to one to disable AArch64 Secure self-hosted debug.
 	 *  Debug exceptions, other than Breakpoint Instruction exceptions, are
 	 *  disabled from all ELs in Secure state.
 	 *
 	 * MDCR_EL3.SPD32: Set to 0b10 to disable AArch32 Secure self-hosted
 	 *  privileged debug from S-EL1.
 	 *
 	 * MDCR_EL3.TDOSA: Set to zero so that EL2 and EL2 System register
 	 *  access to the powerdown debug registers do not trap to EL3.
 	 *
 	 * MDCR_EL3.TDA: Set to zero to allow EL0, EL1 and EL2 access to the
 	 *  debug registers, other than those registers that are controlled by
 	 *  MDCR_EL3.TDOSA.
 	 */
 	mov_imm	x0, ((MDCR_EL3_RESET_VAL | MDCR_SDD_BIT | \
 		      MDCR_SPD32(MDCR_SPD32_DISABLE)) & \
 		    ~(MDCR_TDOSA_BIT | MDCR_TDA_BIT))

 	msr	mdcr_el3, x0

 	/* ---------------------------------------------------------------------
 	 * Enable External Aborts and SError Interrupts now that the exception
 	 * vectors have been setup.
 	 * ---------------------------------------------------------------------
 	 */
 	msr	daifclr, #DAIF_ABT_BIT

 	/* ---------------------------------------------------------------------
 	 * Initialise CPTR_EL3, setting all fields rather than relying on hw.
 	 * All fields are architecturally UNKNOWN on reset.
 	 * ---------------------------------------------------------------------
 	 */
 	mov_imm x0, CPTR_EL3_RESET_VAL
 	msr	cptr_el3, x0

 	/*
 	 * If Data Independent Timing (DIT) functionality is implemented,
 	 * always enable DIT in EL3.
 	 * First assert that the FEAT_DIT build flag matches the feature id
 	 * register value for DIT.
 	 */
 #if ENABLE_FEAT_DIT
 #if ENABLE_ASSERTIONS || ENABLE_FEAT_DIT > 1
 	mrs	x0, id_aa64pfr0_el1
 	ubfx	x0, x0, #ID_AA64PFR0_DIT_SHIFT, #ID_AA64PFR0_DIT_LENGTH
 #if ENABLE_FEAT_DIT > 1
 	cbz	x0, 1f
 #else
 	cmp	x0, #ID_AA64PFR0_DIT_SUPPORTED
 	ASM_ASSERT(eq)
 #endif

 #endif /* ENABLE_ASSERTIONS */
 	mov	x0, #DIT_BIT
 	msr	DIT, x0
 1:
 #endif
 	.endm

 /* -----------------------------------------------------------------------------
  * This is the super set of actions that need to be performed during a cold boot
  * or a warm boot in EL3. This code is shared by BL1 and BL31.
  *
  * This macro will always perform reset handling, architectural initialisations
  * and stack setup. The rest of the actions are optional because they might not
  * be needed, depending on the context in which this macro is called. This is
  * why this macro is parameterised ; each parameter allows to enable/disable
  * some actions.
  *
  *  _init_sctlr:
  *	Whether the macro needs to initialise SCTLR_EL3, including configuring
  *      the endianness of data accesses.
  *
  *  _warm_boot_mailbox:
  *	Whether the macro needs to detect the type of boot (cold/warm). The
  *	detection is based on the platform entrypoint address : if it is zero
  *	then it is a cold boot, otherwise it is a warm boot. In the latter case,
  *	this macro jumps on the platform entrypoint address.
  *
  *  _secondary_cold_boot:
  *	Whether the macro needs to identify the CPU that is calling it: primary
  *	CPU or secondary CPU. The primary CPU will be allowed to carry on with
  *	the platform initialisations, while the secondaries will be put in a
  *	platform-specific state in the meantime.
  *
  *	If the caller knows this macro will only be called by the primary CPU
  *	then this parameter can be defined to 0 to skip this step.
  *
  * _init_memory:
  *	Whether the macro needs to initialise the memory.
  *
  * _init_c_runtime:
  *	Whether the macro needs to initialise the C runtime environment.
  *
  * _exception_vectors:
  *	Address of the exception vectors to program in the VBAR_EL3 register.
  *
  * _pie_fixup_size:
  *	Size of memory region to fixup Global Descriptor Table (GDT).
  *
  *	A non-zero value is expected when firmware needs GDT to be fixed-up.
  *
  * -----------------------------------------------------------------------------
  */
 	.macro el3_entrypoint_common					\
 		_init_sctlr, _warm_boot_mailbox, _secondary_cold_boot,	\
 		_init_memory, _init_c_runtime, _exception_vectors,	\
 		_pie_fixup_size

 	.if \_init_sctlr
 		/* -------------------------------------------------------------
 		 * This is the initialisation of SCTLR_EL3 and so must ensure
 		 * that all fields are explicitly set rather than relying on hw.
 		 * Some fields reset to an IMPLEMENTATION DEFINED value and
 		 * others are architecturally UNKNOWN on reset.
 		 *
 		 * SCTLR.EE: Set the CPU endianness before doing anything that
 		 *  might involve memory reads or writes. Set to zero to select
 		 *  Little Endian.
 		 *
 		 * SCTLR_EL3.WXN: For the EL3 translation regime, this field can
 		 *  force all memory regions that are writeable to be treated as
 		 *  XN (Execute-never). Set to zero so that this control has no
 		 *  effect on memory access permissions.
 		 *
 		 * SCTLR_EL3.SA: Set to zero to disable Stack Alignment check.
 		 *
 		 * SCTLR_EL3.A: Set to zero to disable Alignment fault checking.
 		 *
 		 * SCTLR.DSSBS: Set to zero to disable speculation store bypass
 		 *  safe behaviour upon exception entry to EL3.
 		 * -------------------------------------------------------------
 		 */
 		mov_imm	x0, (SCTLR_RESET_VAL & ~(SCTLR_EE_BIT | SCTLR_WXN_BIT \
 				| SCTLR_SA_BIT | SCTLR_A_BIT | SCTLR_DSSBS_BIT))
 #if ENABLE_FEAT_RAS
 		/* If FEAT_RAS is present assume FEAT_IESB is also present */
 		orr	x0, x0, #SCTLR_IESB_BIT
 #endif
 		msr	sctlr_el3, x0
 		isb
 	.endif /* _init_sctlr */

 	.if \_warm_boot_mailbox
 		/* -------------------------------------------------------------
 		 * This code will be executed for both warm and cold resets.
 		 * Now is the time to distinguish between the two.
 		 * Query the platform entrypoint address and if it is not zero
 		 * then it means it is a warm boot so jump to this address.
 		 * -------------------------------------------------------------
 		 */
 		bl	plat_get_my_entrypoint
 		cbz	x0, do_cold_boot
 		br	x0

 	do_cold_boot:
 	.endif /* _warm_boot_mailbox */

 	.if \_pie_fixup_size
 #if ENABLE_PIE
 		/*
 		 * ------------------------------------------------------------
 		 * If PIE is enabled fixup the Global descriptor Table only
 		 * once during primary core cold boot path.
 		 *
 		 * Compile time base address, required for fixup, is calculated
 		 * using "pie_fixup" label present within first page.
 		 * ------------------------------------------------------------
 		 */
 	pie_fixup:
 		ldr	x0, =pie_fixup
 		and	x0, x0, #~(PAGE_SIZE_MASK)
 		mov_imm	x1, \_pie_fixup_size
 		add	x1, x1, x0
 		bl	fixup_gdt_reloc
 #endif /* ENABLE_PIE */
 	.endif /* _pie_fixup_size */

 	/* ---------------------------------------------------------------------
 	 * Set the exception vectors.
 	 * ---------------------------------------------------------------------
 	 */
 	adr	x0, \_exception_vectors
 	msr	vbar_el3, x0
 	isb

 #if !(defined(IMAGE_BL2) && ENABLE_RME)
 	/* ---------------------------------------------------------------------
 	 * It is a cold boot.
 	 * Perform any processor specific actions upon reset e.g. cache, TLB
 	 * invalidations etc.
 	 * ---------------------------------------------------------------------
 	 */
 	bl	reset_handler
 #endif

 	el3_arch_init_common

 	.if \_secondary_cold_boot
 		/* -------------------------------------------------------------
 		 * Check if this is a primary or secondary CPU cold boot.
 		 * The primary CPU will set up the platform while the
 		 * secondaries are placed in a platform-specific state until the
 		 * primary CPU performs the necessary actions to bring them out
 		 * of that state and allows entry into the OS.
 		 * -------------------------------------------------------------
 		 */
 		bl	plat_is_my_cpu_primary
 		cbnz	w0, do_primary_cold_boot

 		/* This is a cold boot on a secondary CPU */
 		bl	plat_secondary_cold_boot_setup
 		/* plat_secondary_cold_boot_setup() is not supposed to return */
 		bl	el3_panic

 	do_primary_cold_boot:
 	.endif /* _secondary_cold_boot */

 	/* ---------------------------------------------------------------------
 	 * Initialize memory now. Secondary CPU initialization won't get to this
 	 * point.
 	 * ---------------------------------------------------------------------
 	 */

 	.if \_init_memory
 		bl	platform_mem_init
 	.endif /* _init_memory */

 	/* ---------------------------------------------------------------------
 	 * Init C runtime environment:
 	 *   - Zero-initialise the NOBITS sections. There are 2 of them:
 	 *       - the .bss section;
 	 *       - the coherent memory section (if any).
 	 *   - Relocate the data section from ROM to RAM, if required.
 	 * ---------------------------------------------------------------------
 	 */
 	.if \_init_c_runtime
 #if defined(IMAGE_BL31) || (defined(IMAGE_BL2) && \
 	((RESET_TO_BL2 && BL2_INV_DCACHE) || ENABLE_RME))
 		/* -------------------------------------------------------------
 		 * Invalidate the RW memory used by the BL31 image. This
 		 * includes the data and NOBITS sections. This is done to
 		 * safeguard against possible corruption of this memory by
 		 * dirty cache lines in a system cache as a result of use by
 		 * an earlier boot loader stage. If PIE is enabled however,
 		 * RO sections including the GOT may be modified during
                  * pie fixup. Therefore, to be on the safe side, invalidate
 		 * the entire image region if PIE is enabled.
 		 * -------------------------------------------------------------
 		 */
 #if ENABLE_PIE
 #if SEPARATE_CODE_AND_RODATA
 		adrp	x0, __TEXT_START__
 		add	x0, x0, :lo12:__TEXT_START__
 #else
 		adrp	x0, __RO_START__
 		add	x0, x0, :lo12:__RO_START__
 #endif /* SEPARATE_CODE_AND_RODATA */
 #else
 		adrp	x0, __RW_START__
 		add	x0, x0, :lo12:__RW_START__
 #endif /* ENABLE_PIE */
 		adrp	x1, __RW_END__
 		add	x1, x1, :lo12:__RW_END__
 		sub	x1, x1, x0
 		bl	inv_dcache_range
 #if defined(IMAGE_BL31) && SEPARATE_NOBITS_REGION
 		adrp	x0, __NOBITS_START__
 		add	x0, x0, :lo12:__NOBITS_START__
 		adrp	x1, __NOBITS_END__
 		add	x1, x1, :lo12:__NOBITS_END__
 		sub	x1, x1, x0
 		bl	inv_dcache_range
 #endif
 #if defined(IMAGE_BL2) && SEPARATE_BL2_NOLOAD_REGION
 		adrp	x0, __BL2_NOLOAD_START__
 		add	x0, x0, :lo12:__BL2_NOLOAD_START__
 		adrp	x1, __BL2_NOLOAD_END__
 		add	x1, x1, :lo12:__BL2_NOLOAD_END__
 		sub	x1, x1, x0
 		bl	inv_dcache_range
 #endif
 #endif
 		adrp	x0, __BSS_START__
 		add	x0, x0, :lo12:__BSS_START__

 		adrp	x1, __BSS_END__
 		add	x1, x1, :lo12:__BSS_END__
 		sub	x1, x1, x0
 		bl	zeromem

 #if USE_COHERENT_MEM
 		adrp	x0, __COHERENT_RAM_START__
 		add	x0, x0, :lo12:__COHERENT_RAM_START__
 		adrp	x1, __COHERENT_RAM_END_UNALIGNED__
 		add	x1, x1, :lo12: __COHERENT_RAM_END_UNALIGNED__
 		sub	x1, x1, x0
 		bl	zeromem
 #endif

 #if defined(IMAGE_BL1) ||	\
 	(defined(IMAGE_BL2) && RESET_TO_BL2 && BL2_IN_XIP_MEM)
 		adrp	x0, __DATA_RAM_START__
 		add	x0, x0, :lo12:__DATA_RAM_START__
 		adrp	x1, __DATA_ROM_START__
 		add	x1, x1, :lo12:__DATA_ROM_START__
 		adrp	x2, __DATA_RAM_END__
 		add	x2, x2, :lo12:__DATA_RAM_END__
 		sub	x2, x2, x0
 		bl	memcpy16
 #endif
 	.endif /* _init_c_runtime */

 	/* ---------------------------------------------------------------------
 	 * Use SP_EL0 for the C runtime stack.
 	 * ---------------------------------------------------------------------
 	 */
 	msr	spsel, #0

 	/* ---------------------------------------------------------------------
 	 * Allocate a stack whose memory will be marked as Normal-IS-WBWA when
 	 * the MMU is enabled. There is no risk of reading stale stack memory
 	 * after enabling the MMU as only the primary CPU is running at the
 	 * moment.
 	 * ---------------------------------------------------------------------
 	 */
 	bl	plat_set_my_stack

 #if STACK_PROTECTOR_ENABLED
 	.if \_init_c_runtime
 	bl	update_stack_protector_canary
 	.endif /* _init_c_runtime */
 #endif
 	.endm

 	.macro	apply_at_speculative_wa
 #if ERRATA_SPECULATIVE_AT
 	/*
 	 * This function expects x30 has been saved.
 	 * Also, save x29 which will be used in the called function.
 	 */
 	str	x29, [sp, #CTX_GPREGS_OFFSET + CTX_GPREG_X29]
 	bl	save_and_update_ptw_el1_sys_regs
 	ldr	x29, [sp, #CTX_GPREGS_OFFSET + CTX_GPREG_X29]
 #endif
 	.endm

 	.macro	restore_ptw_el1_sys_regs
 #if ERRATA_SPECULATIVE_AT
 	/* -----------------------------------------------------------
 	 * In case of ERRATA_SPECULATIVE_AT, must follow below order
 	 * to ensure that page table walk is not enabled until
 	 * restoration of all EL1 system registers. TCR_EL1 register
 	 * should be updated at the end which restores previous page
 	 * table walk setting of stage1 i.e.(TCR_EL1.EPDx) bits. ISB
 	 * ensures that CPU does below steps in order.
 	 *
 	 * 1. Ensure all other system registers are written before
 	 *    updating SCTLR_EL1 using ISB.
 	 * 2. Restore SCTLR_EL1 register.
 	 * 3. Ensure SCTLR_EL1 written successfully using ISB.
 	 * 4. Restore TCR_EL1 register.
 	 * -----------------------------------------------------------
 	 */
 	isb
 	ldp	x28, x29, [sp, #CTX_EL1_SYSREGS_OFFSET + CTX_SCTLR_EL1]
 	msr	sctlr_el1, x28
 	isb
 	msr	tcr_el1, x29
 #endif
 	.endm

 /* -----------------------------------------------------------------
  * The below macro reads SCR_EL3 from the context structure to
  * determine the security state of the context upon ERET.
  * ------------------------------------------------------------------
  */
 	.macro get_security_state _ret:req, _scr_reg:req
 		ubfx 	\_ret, \_scr_reg, #SCR_NSE_SHIFT, #1
 		cmp 	\_ret, #1
 		beq 	realm_state
 		bfi	\_ret, \_scr_reg, #0, #1
 		b 	end
 	realm_state:
 		mov 	\_ret, #2
 	end:
 	.endm

 #endif /* EL3_COMMON_MACROS_S */
	/*
	* Copyright (c) 2015-2023, Arm Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#ifndef EL3_COMMON_MACROS_S
	#define EL3_COMMON_MACROS_S

	#include <arch.h>
	#include <asm_macros.S>
	#include <assert_macros.S>
	#include <context.h>
	#include <lib/xlat_tables/xlat_tables_defs.h>

	/*
	* Helper macro to initialise EL3 registers we care about.
	*/
	.macro el3_arch_init_common
	/* ---------------------------------------------------------------------
	* SCTLR_EL3 has already been initialised - read current value before
	* modifying.
	*
	* SCTLR_EL3.I: Enable the instruction cache.
	*
	* SCTLR_EL3.SA: Enable Stack Alignment check. A SP alignment fault
	* exception is generated if a load or store instruction executed at
	* EL3 uses the SP as the base address and the SP is not aligned to a
	* 16-byte boundary.
	*
	* SCTLR_EL3.A: Enable Alignment fault checking. All instructions that
	* load or store one or more registers have an alignment check that the
	* address being accessed is aligned to the size of the data element(s)
	* being accessed.
	* ---------------------------------------------------------------------
	*/
	mov x1, #(SCTLR_I_BIT \| SCTLR_A_BIT \| SCTLR_SA_BIT)
	mrs x0, sctlr_el3
	orr x0, x0, x1
	msr sctlr_el3, x0
	isb

	#ifdef IMAGE_BL31
	/* ---------------------------------------------------------------------
	* Initialise the per-cpu cache pointer to the CPU.
	* This is done early to enable crash reporting to have access to crash
	* stack. Since crash reporting depends on cpu_data to report the
	* unhandled exception, not doing so can lead to recursive exceptions
	* due to a NULL TPIDR_EL3.
	* ---------------------------------------------------------------------
	*/
	bl init_cpu_data_ptr
	#endif /* IMAGE_BL31 */

	/* ---------------------------------------------------------------------
	* Initialise SCR_EL3, setting all fields rather than relying on hw.
	* All fields are architecturally UNKNOWN on reset. The following fields
	* do not change during the TF lifetime. The remaining fields are set to
	* zero here but are updated ahead of transitioning to a lower EL in the
	* function cm_init_context_common().
	*
	* SCR_EL3.SIF: Set to one to disable instruction fetches from
	* Non-secure memory.
	*
	* SCR_EL3.EA: Set to one to route External Aborts and SError Interrupts
	* to EL3 when executing at any EL.
	* ---------------------------------------------------------------------
	*/
	mov_imm x0, (SCR_RESET_VAL \| SCR_EA_BIT \| SCR_SIF_BIT)
	msr scr_el3, x0

	/* ---------------------------------------------------------------------
	* Initialise MDCR_EL3, setting all fields rather than relying on hw.
	* Some fields are architecturally UNKNOWN on reset.
	*
	* MDCR_EL3.SDD: Set to one to disable AArch64 Secure self-hosted debug.
	* Debug exceptions, other than Breakpoint Instruction exceptions, are
	* disabled from all ELs in Secure state.
	*
	* MDCR_EL3.SPD32: Set to 0b10 to disable AArch32 Secure self-hosted
	* privileged debug from S-EL1.
	*
	* MDCR_EL3.TDOSA: Set to zero so that EL2 and EL2 System register
	* access to the powerdown debug registers do not trap to EL3.
	*
	* MDCR_EL3.TDA: Set to zero to allow EL0, EL1 and EL2 access to the
	* debug registers, other than those registers that are controlled by
	* MDCR_EL3.TDOSA.
	*/
	mov_imm x0, ((MDCR_EL3_RESET_VAL \| MDCR_SDD_BIT \| \
	MDCR_SPD32(MDCR_SPD32_DISABLE)) & \
	~(MDCR_TDOSA_BIT \| MDCR_TDA_BIT))

	msr mdcr_el3, x0

	/* ---------------------------------------------------------------------
	* Enable External Aborts and SError Interrupts now that the exception
	* vectors have been setup.
	* ---------------------------------------------------------------------
	*/
	msr daifclr, #DAIF_ABT_BIT

	/* ---------------------------------------------------------------------
	* Initialise CPTR_EL3, setting all fields rather than relying on hw.
	* All fields are architecturally UNKNOWN on reset.
	* ---------------------------------------------------------------------
	*/
	mov_imm x0, CPTR_EL3_RESET_VAL
	msr cptr_el3, x0

	/*
	* If Data Independent Timing (DIT) functionality is implemented,
	* always enable DIT in EL3.
	* First assert that the FEAT_DIT build flag matches the feature id
	* register value for DIT.
	*/
	#if ENABLE_FEAT_DIT
	#if ENABLE_ASSERTIONS \|\| ENABLE_FEAT_DIT > 1
	mrs x0, id_aa64pfr0_el1
	ubfx x0, x0, #ID_AA64PFR0_DIT_SHIFT, #ID_AA64PFR0_DIT_LENGTH
	#if ENABLE_FEAT_DIT > 1
	cbz x0, 1f
	#else
	cmp x0, #ID_AA64PFR0_DIT_SUPPORTED
	ASM_ASSERT(eq)
	#endif

	#endif /* ENABLE_ASSERTIONS */
	mov x0, #DIT_BIT
	msr DIT, x0
	1:
	#endif
	.endm

	/* -----------------------------------------------------------------------------
	* This is the super set of actions that need to be performed during a cold boot
	* or a warm boot in EL3. This code is shared by BL1 and BL31.
	*
	* This macro will always perform reset handling, architectural initialisations
	* and stack setup. The rest of the actions are optional because they might not
	* be needed, depending on the context in which this macro is called. This is
	* why this macro is parameterised ; each parameter allows to enable/disable
	* some actions.
	*
	* _init_sctlr:
	* Whether the macro needs to initialise SCTLR_EL3, including configuring
	* the endianness of data accesses.
	*
	* _warm_boot_mailbox:
	* Whether the macro needs to detect the type of boot (cold/warm). The
	* detection is based on the platform entrypoint address : if it is zero
	* then it is a cold boot, otherwise it is a warm boot. In the latter case,
	* this macro jumps on the platform entrypoint address.
	*
	* _secondary_cold_boot:
	* Whether the macro needs to identify the CPU that is calling it: primary
	* CPU or secondary CPU. The primary CPU will be allowed to carry on with
	* the platform initialisations, while the secondaries will be put in a
	* platform-specific state in the meantime.
	*
	* If the caller knows this macro will only be called by the primary CPU
	* then this parameter can be defined to 0 to skip this step.
	*
	* _init_memory:
	* Whether the macro needs to initialise the memory.
	*
	* _init_c_runtime:
	* Whether the macro needs to initialise the C runtime environment.
	*
	* _exception_vectors:
	* Address of the exception vectors to program in the VBAR_EL3 register.
	*
	* _pie_fixup_size:
	* Size of memory region to fixup Global Descriptor Table (GDT).
	*
	* A non-zero value is expected when firmware needs GDT to be fixed-up.
	*
	* -----------------------------------------------------------------------------
	*/
	.macro el3_entrypoint_common \
	_init_sctlr, _warm_boot_mailbox, _secondary_cold_boot, \
	_init_memory, _init_c_runtime, _exception_vectors, \
	_pie_fixup_size

	.if \_init_sctlr
	/* -------------------------------------------------------------
	* This is the initialisation of SCTLR_EL3 and so must ensure
	* that all fields are explicitly set rather than relying on hw.
	* Some fields reset to an IMPLEMENTATION DEFINED value and
	* others are architecturally UNKNOWN on reset.
	*
	* SCTLR.EE: Set the CPU endianness before doing anything that
	* might involve memory reads or writes. Set to zero to select
	* Little Endian.
	*
	* SCTLR_EL3.WXN: For the EL3 translation regime, this field can
	* force all memory regions that are writeable to be treated as
	* XN (Execute-never). Set to zero so that this control has no
	* effect on memory access permissions.
	*
	* SCTLR_EL3.SA: Set to zero to disable Stack Alignment check.
	*
	* SCTLR_EL3.A: Set to zero to disable Alignment fault checking.
	*
	* SCTLR.DSSBS: Set to zero to disable speculation store bypass
	* safe behaviour upon exception entry to EL3.
	* -------------------------------------------------------------
	*/
	mov_imm x0, (SCTLR_RESET_VAL & ~(SCTLR_EE_BIT \| SCTLR_WXN_BIT \
	\| SCTLR_SA_BIT \| SCTLR_A_BIT \| SCTLR_DSSBS_BIT))
	#if ENABLE_FEAT_RAS
	/* If FEAT_RAS is present assume FEAT_IESB is also present */
	orr x0, x0, #SCTLR_IESB_BIT
	#endif
	msr sctlr_el3, x0
	isb
	.endif /* _init_sctlr */

	.if \_warm_boot_mailbox
	/* -------------------------------------------------------------
	* This code will be executed for both warm and cold resets.
	* Now is the time to distinguish between the two.
	* Query the platform entrypoint address and if it is not zero
	* then it means it is a warm boot so jump to this address.
	* -------------------------------------------------------------
	*/
	bl plat_get_my_entrypoint
	cbz x0, do_cold_boot
	br x0

	do_cold_boot:
	.endif /* _warm_boot_mailbox */

	.if \_pie_fixup_size
	#if ENABLE_PIE
	/*
	* ------------------------------------------------------------
	* If PIE is enabled fixup the Global descriptor Table only
	* once during primary core cold boot path.
	*
	* Compile time base address, required for fixup, is calculated
	* using "pie_fixup" label present within first page.
	* ------------------------------------------------------------
	*/
	pie_fixup:
	ldr x0, =pie_fixup
	and x0, x0, #~(PAGE_SIZE_MASK)
	mov_imm x1, \_pie_fixup_size
	add x1, x1, x0
	bl fixup_gdt_reloc
	#endif /* ENABLE_PIE */
	.endif /* _pie_fixup_size */

	/* ---------------------------------------------------------------------
	* Set the exception vectors.
	* ---------------------------------------------------------------------
	*/
	adr x0, \_exception_vectors
	msr vbar_el3, x0
	isb

	#if !(defined(IMAGE_BL2) && ENABLE_RME)
	/* ---------------------------------------------------------------------
	* It is a cold boot.
	* Perform any processor specific actions upon reset e.g. cache, TLB
	* invalidations etc.
	* ---------------------------------------------------------------------
	*/
	bl reset_handler
	#endif

	el3_arch_init_common

	.if \_secondary_cold_boot
	/* -------------------------------------------------------------
	* Check if this is a primary or secondary CPU cold boot.
	* The primary CPU will set up the platform while the
	* secondaries are placed in a platform-specific state until the
	* primary CPU performs the necessary actions to bring them out
	* of that state and allows entry into the OS.
	* -------------------------------------------------------------
	*/
	bl plat_is_my_cpu_primary
	cbnz w0, do_primary_cold_boot

	/* This is a cold boot on a secondary CPU */
	bl plat_secondary_cold_boot_setup
	/* plat_secondary_cold_boot_setup() is not supposed to return */
	bl el3_panic

	do_primary_cold_boot:
	.endif /* _secondary_cold_boot */

	/* ---------------------------------------------------------------------
	* Initialize memory now. Secondary CPU initialization won't get to this
	* point.
	* ---------------------------------------------------------------------
	*/

	.if \_init_memory
	bl platform_mem_init
	.endif /* _init_memory */

	/* ---------------------------------------------------------------------
	* Init C runtime environment:
	* - Zero-initialise the NOBITS sections. There are 2 of them:
	* - the .bss section;
	* - the coherent memory section (if any).
	* - Relocate the data section from ROM to RAM, if required.
	* ---------------------------------------------------------------------
	*/
	.if \_init_c_runtime
	#if defined(IMAGE_BL31) \|\| (defined(IMAGE_BL2) && \
	((RESET_TO_BL2 && BL2_INV_DCACHE) \|\| ENABLE_RME))
	/* -------------------------------------------------------------
	* Invalidate the RW memory used by the BL31 image. This
	* includes the data and NOBITS sections. This is done to
	* safeguard against possible corruption of this memory by
	* dirty cache lines in a system cache as a result of use by
	* an earlier boot loader stage. If PIE is enabled however,
	* RO sections including the GOT may be modified during
	* pie fixup. Therefore, to be on the safe side, invalidate
	* the entire image region if PIE is enabled.
	* -------------------------------------------------------------
	*/
	#if ENABLE_PIE
	#if SEPARATE_CODE_AND_RODATA
	adrp x0, __TEXT_START__
	add x0, x0, :lo12:__TEXT_START__
	#else
	adrp x0, __RO_START__
	add x0, x0, :lo12:__RO_START__
	#endif /* SEPARATE_CODE_AND_RODATA */
	#else
	adrp x0, __RW_START__
	add x0, x0, :lo12:__RW_START__
	#endif /* ENABLE_PIE */
	adrp x1, __RW_END__
	add x1, x1, :lo12:__RW_END__
	sub x1, x1, x0
	bl inv_dcache_range
	#if defined(IMAGE_BL31) && SEPARATE_NOBITS_REGION
	adrp x0, __NOBITS_START__
	add x0, x0, :lo12:__NOBITS_START__
	adrp x1, __NOBITS_END__
	add x1, x1, :lo12:__NOBITS_END__
	sub x1, x1, x0
	bl inv_dcache_range
	#endif
	#if defined(IMAGE_BL2) && SEPARATE_BL2_NOLOAD_REGION
	adrp x0, __BL2_NOLOAD_START__
	add x0, x0, :lo12:__BL2_NOLOAD_START__
	adrp x1, __BL2_NOLOAD_END__
	add x1, x1, :lo12:__BL2_NOLOAD_END__
	sub x1, x1, x0
	bl inv_dcache_range
	#endif
	#endif
	adrp x0, __BSS_START__
	add x0, x0, :lo12:__BSS_START__

	adrp x1, __BSS_END__
	add x1, x1, :lo12:__BSS_END__
	sub x1, x1, x0
	bl zeromem

	#if USE_COHERENT_MEM
	adrp x0, __COHERENT_RAM_START__
	add x0, x0, :lo12:__COHERENT_RAM_START__
	adrp x1, __COHERENT_RAM_END_UNALIGNED__
	add x1, x1, :lo12: __COHERENT_RAM_END_UNALIGNED__
	sub x1, x1, x0
	bl zeromem
	#endif

	#if defined(IMAGE_BL1) \|\| \
	(defined(IMAGE_BL2) && RESET_TO_BL2 && BL2_IN_XIP_MEM)
	adrp x0, __DATA_RAM_START__
	add x0, x0, :lo12:__DATA_RAM_START__
	adrp x1, __DATA_ROM_START__
	add x1, x1, :lo12:__DATA_ROM_START__
	adrp x2, __DATA_RAM_END__
	add x2, x2, :lo12:__DATA_RAM_END__
	sub x2, x2, x0
	bl memcpy16
	#endif
	.endif /* _init_c_runtime */

	/* ---------------------------------------------------------------------
	* Use SP_EL0 for the C runtime stack.
	* ---------------------------------------------------------------------
	*/
	msr spsel, #0

	/* ---------------------------------------------------------------------
	* Allocate a stack whose memory will be marked as Normal-IS-WBWA when
	* the MMU is enabled. There is no risk of reading stale stack memory
	* after enabling the MMU as only the primary CPU is running at the
	* moment.
	* ---------------------------------------------------------------------
	*/
	bl plat_set_my_stack

	#if STACK_PROTECTOR_ENABLED
	.if \_init_c_runtime
	bl update_stack_protector_canary
	.endif /* _init_c_runtime */
	#endif
	.endm

	.macro apply_at_speculative_wa
	#if ERRATA_SPECULATIVE_AT
	/*
	* This function expects x30 has been saved.
	* Also, save x29 which will be used in the called function.
	*/
	str x29, [sp, #CTX_GPREGS_OFFSET + CTX_GPREG_X29]
	bl save_and_update_ptw_el1_sys_regs
	ldr x29, [sp, #CTX_GPREGS_OFFSET + CTX_GPREG_X29]
	#endif
	.endm

	.macro restore_ptw_el1_sys_regs
	#if ERRATA_SPECULATIVE_AT
	/* -----------------------------------------------------------
	* In case of ERRATA_SPECULATIVE_AT, must follow below order
	* to ensure that page table walk is not enabled until
	* restoration of all EL1 system registers. TCR_EL1 register
	* should be updated at the end which restores previous page
	* table walk setting of stage1 i.e.(TCR_EL1.EPDx) bits. ISB
	* ensures that CPU does below steps in order.
	*
	* 1. Ensure all other system registers are written before
	* updating SCTLR_EL1 using ISB.
	* 2. Restore SCTLR_EL1 register.
	* 3. Ensure SCTLR_EL1 written successfully using ISB.
	* 4. Restore TCR_EL1 register.
	* -----------------------------------------------------------
	*/
	isb
	ldp x28, x29, [sp, #CTX_EL1_SYSREGS_OFFSET + CTX_SCTLR_EL1]
	msr sctlr_el1, x28
	isb
	msr tcr_el1, x29
	#endif
	.endm

	/* -----------------------------------------------------------------
	* The below macro reads SCR_EL3 from the context structure to
	* determine the security state of the context upon ERET.
	* ------------------------------------------------------------------
	*/
	.macro get_security_state _ret:req, _scr_reg:req
	ubfx \_ret, \_scr_reg, #SCR_NSE_SHIFT, #1
	cmp \_ret, #1
	beq realm_state
	bfi \_ret, \_scr_reg, #0, #1
	b end
	realm_state:
	mov \_ret, #2
	end:
	.endm

	#endif /* EL3_COMMON_MACROS_S */