bl32/tsp/aarch64/tsp_entrypoint.S - filogic/atf - Gitiles

 /*
  * Copyright (c) 2013-2016, ARM Limited and Contributors. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are met:
  *
  * Redistributions of source code must retain the above copyright notice, this
  * list of conditions and the following disclaimer.
  *
  * Redistributions in binary form must reproduce the above copyright notice,
  * this list of conditions and the following disclaimer in the documentation
  * and/or other materials provided with the distribution.
  *
  * Neither the name of ARM nor the names of its contributors may be used
  * to endorse or promote products derived from this software without specific
  * prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
  * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
  * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
  * POSSIBILITY OF SUCH DAMAGE.
  */

 #include <arch.h>
 #include <asm_macros.S>
 #include <tsp.h>
 #include <xlat_tables.h>
 #include "../tsp_private.h"


 	.globl	tsp_entrypoint
 	.globl  tsp_vector_table


 	/* ---------------------------------------------
 	 * Populate the params in x0-x7 from the pointer
 	 * to the smc args structure in x0.
 	 * ---------------------------------------------
 	 */
 	.macro restore_args_call_smc
 	ldp	x6, x7, [x0, #TSP_ARG6]
 	ldp	x4, x5, [x0, #TSP_ARG4]
 	ldp	x2, x3, [x0, #TSP_ARG2]
 	ldp	x0, x1, [x0, #TSP_ARG0]
 	smc	#0
 	.endm

 	.macro	save_eret_context reg1 reg2
 	mrs	\reg1, elr_el1
 	mrs	\reg2, spsr_el1
 	stp	\reg1, \reg2, [sp, #-0x10]!
 	stp	x30, x18, [sp, #-0x10]!
 	.endm

 	.macro restore_eret_context reg1 reg2
 	ldp	x30, x18, [sp], #0x10
 	ldp	\reg1, \reg2, [sp], #0x10
 	msr	elr_el1, \reg1
 	msr	spsr_el1, \reg2
 	.endm

 	.section	.text, "ax"
 	.align 3

 func tsp_entrypoint

 	/* ---------------------------------------------
 	 * Set the exception vector to something sane.
 	 * ---------------------------------------------
 	 */
 	adr	x0, tsp_exceptions
 	msr	vbar_el1, x0
 	isb

 	/* ---------------------------------------------
 	 * Enable the SError interrupt now that the
 	 * exception vectors have been setup.
 	 * ---------------------------------------------
 	 */
 	msr	daifclr, #DAIF_ABT_BIT

 	/* ---------------------------------------------
 	 * Enable the instruction cache, stack pointer
 	 * and data access alignment checks
 	 * ---------------------------------------------
 	 */
 	mov	x1, #(SCTLR_I_BIT | SCTLR_A_BIT | SCTLR_SA_BIT)
 	mrs	x0, sctlr_el1
 	orr	x0, x0, x1
 	msr	sctlr_el1, x0
 	isb

 	/* ---------------------------------------------
 	 * Invalidate the RW memory used by the BL32
 	 * 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.
 	 * ---------------------------------------------
 	 */
 	adr	x0, __RW_START__
 	adr	x1, __RW_END__
 	sub	x1, x1, x0
 	bl	inv_dcache_range

 	/* ---------------------------------------------
 	 * Zero out NOBITS sections. There are 2 of them:
 	 *   - the .bss section;
 	 *   - the coherent memory section.
 	 * ---------------------------------------------
 	 */
 	ldr	x0, =__BSS_START__
 	ldr	x1, =__BSS_SIZE__
 	bl	zeromem16

 #if USE_COHERENT_MEM
 	ldr	x0, =__COHERENT_RAM_START__
 	ldr	x1, =__COHERENT_RAM_UNALIGNED_SIZE__
 	bl	zeromem16
 #endif

 	/* --------------------------------------------
 	 * 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

 	/* ---------------------------------------------
 	 * Perform early platform setup & platform
 	 * specific early arch. setup e.g. mmu setup
 	 * ---------------------------------------------
 	 */
 	bl	tsp_early_platform_setup
 	bl	tsp_plat_arch_setup

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

 	/* ---------------------------------------------
 	 * Tell TSPD that we are done initialising
 	 * ---------------------------------------------
 	 */
 	mov	x1, x0
 	mov	x0, #TSP_ENTRY_DONE
 	smc	#0

 tsp_entrypoint_panic:
 	b	tsp_entrypoint_panic
 endfunc tsp_entrypoint


 	/* -------------------------------------------
 	 * Table of entrypoint vectors provided to the
 	 * TSPD for the various entrypoints
 	 * -------------------------------------------
 	 */
 func tsp_vector_table
 	b	tsp_std_smc_entry
 	b	tsp_fast_smc_entry
 	b	tsp_cpu_on_entry
 	b	tsp_cpu_off_entry
 	b	tsp_cpu_resume_entry
 	b	tsp_cpu_suspend_entry
 	b	tsp_sel1_intr_entry
 	b	tsp_system_off_entry
 	b	tsp_system_reset_entry
 endfunc tsp_vector_table

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD when this
 	 * cpu is to be turned off through a CPU_OFF
 	 * psci call to ask the TSP to perform any
 	 * bookeeping necessary. In the current
 	 * implementation, the TSPD expects the TSP to
 	 * re-initialise its state so nothing is done
 	 * here except for acknowledging the request.
 	 * ---------------------------------------------
 	 */
 func tsp_cpu_off_entry
 	bl	tsp_cpu_off_main
 	restore_args_call_smc
 endfunc tsp_cpu_off_entry

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD when the
 	 * system is about to be switched off (through
 	 * a SYSTEM_OFF psci call) to ask the TSP to
 	 * perform any necessary bookkeeping.
 	 * ---------------------------------------------
 	 */
 func tsp_system_off_entry
 	bl	tsp_system_off_main
 	restore_args_call_smc
 endfunc tsp_system_off_entry

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD when the
 	 * system is about to be reset (through a
 	 * SYSTEM_RESET psci call) to ask the TSP to
 	 * perform any necessary bookkeeping.
 	 * ---------------------------------------------
 	 */
 func tsp_system_reset_entry
 	bl	tsp_system_reset_main
 	restore_args_call_smc
 endfunc tsp_system_reset_entry

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD when this
 	 * cpu is turned on using a CPU_ON psci call to
 	 * ask the TSP to initialise itself i.e. setup
 	 * the mmu, stacks etc. Minimal architectural
 	 * state will be initialised by the TSPD when
 	 * this function is entered i.e. Caches and MMU
 	 * will be turned off, the execution state
 	 * will be aarch64 and exceptions masked.
 	 * ---------------------------------------------
 	 */
 func tsp_cpu_on_entry
 	/* ---------------------------------------------
 	 * Set the exception vector to something sane.
 	 * ---------------------------------------------
 	 */
 	adr	x0, tsp_exceptions
 	msr	vbar_el1, x0
 	isb

 	/* Enable the SError interrupt */
 	msr	daifclr, #DAIF_ABT_BIT

 	/* ---------------------------------------------
 	 * Enable the instruction cache, stack pointer
 	 * and data access alignment checks
 	 * ---------------------------------------------
 	 */
 	mov	x1, #(SCTLR_I_BIT | SCTLR_A_BIT | SCTLR_SA_BIT)
 	mrs	x0, sctlr_el1
 	orr	x0, x0, x1
 	msr	sctlr_el1, x0
 	isb

 	/* --------------------------------------------
 	 * Give ourselves a stack whose memory will be
 	 * marked as Normal-IS-WBWA when the MMU is
 	 * enabled.
 	 * --------------------------------------------
 	 */
 	bl	plat_set_my_stack

 	/* --------------------------------------------
 	 * Enable the MMU with the DCache disabled. It
 	 * is safe to use stacks allocated in normal
 	 * memory as a result. All memory accesses are
 	 * marked nGnRnE when the MMU is disabled. So
 	 * all the stack writes will make it to memory.
 	 * All memory accesses are marked Non-cacheable
 	 * when the MMU is enabled but D$ is disabled.
 	 * So used stack memory is guaranteed to be
 	 * visible immediately after the MMU is enabled
 	 * Enabling the DCache at the same time as the
 	 * MMU can lead to speculatively fetched and
 	 * possibly stale stack memory being read from
 	 * other caches. This can lead to coherency
 	 * issues.
 	 * --------------------------------------------
 	 */
 	mov	x0, #DISABLE_DCACHE
 	bl	bl32_plat_enable_mmu

 	/* ---------------------------------------------
 	 * Enable the Data cache now that the MMU has
 	 * been enabled. The stack has been unwound. It
 	 * will be written first before being read. This
 	 * will invalidate any stale cache lines resi-
 	 * -dent in other caches. We assume that
 	 * interconnect coherency has been enabled for
 	 * this cluster by EL3 firmware.
 	 * ---------------------------------------------
 	 */
 	mrs	x0, sctlr_el1
 	orr	x0, x0, #SCTLR_C_BIT
 	msr	sctlr_el1, x0
 	isb

 	/* ---------------------------------------------
 	 * Enter C runtime to perform any remaining
 	 * book keeping
 	 * ---------------------------------------------
 	 */
 	bl	tsp_cpu_on_main
 	restore_args_call_smc

 	/* Should never reach here */
 tsp_cpu_on_entry_panic:
 	b	tsp_cpu_on_entry_panic
 endfunc tsp_cpu_on_entry

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD when this
 	 * cpu is to be suspended through a CPU_SUSPEND
 	 * psci call to ask the TSP to perform any
 	 * bookeeping necessary. In the current
 	 * implementation, the TSPD saves and restores
 	 * the EL1 state.
 	 * ---------------------------------------------
 	 */
 func tsp_cpu_suspend_entry
 	bl	tsp_cpu_suspend_main
 	restore_args_call_smc
 endfunc tsp_cpu_suspend_entry

 	/*-------------------------------------------------
 	 * This entrypoint is used by the TSPD to pass
 	 * control for `synchronously` handling a S-EL1
 	 * Interrupt which was triggered while executing
 	 * in normal world. 'x0' contains a magic number
 	 * which indicates this. TSPD expects control to
 	 * be handed back at the end of interrupt
 	 * processing. This is done through an SMC.
 	 * The handover agreement is:
 	 *
 	 * 1. PSTATE.DAIF are set upon entry. 'x1' has
 	 *    the ELR_EL3 from the non-secure state.
 	 * 2. TSP has to preserve the callee saved
 	 *    general purpose registers, SP_EL1/EL0 and
 	 *    LR.
 	 * 3. TSP has to preserve the system and vfp
 	 *    registers (if applicable).
 	 * 4. TSP can use 'x0-x18' to enable its C
 	 *    runtime.
 	 * 5. TSP returns to TSPD using an SMC with
 	 *    'x0' = TSP_HANDLED_S_EL1_INTR
 	 * ------------------------------------------------
 	 */
 func	tsp_sel1_intr_entry
 #if DEBUG
 	mov_imm	x2, TSP_HANDLE_SEL1_INTR_AND_RETURN
 	cmp	x0, x2
 	b.ne	tsp_sel1_int_entry_panic
 #endif
 	/*-------------------------------------------------
 	 * Save any previous context needed to perform
 	 * an exception return from S-EL1 e.g. context
 	 * from a previous Non secure Interrupt.
 	 * Update statistics and handle the S-EL1
 	 * interrupt before returning to the TSPD.
 	 * IRQ/FIQs are not enabled since that will
 	 * complicate the implementation. Execution
 	 * will be transferred back to the normal world
 	 * in any case. The handler can return 0
 	 * if the interrupt was handled or TSP_PREEMPTED
 	 * if the expected interrupt was preempted
 	 * by an interrupt that should be handled in EL3
 	 * e.g. Group 0 interrupt in GICv3. In both
 	 * the cases switch to EL3 using SMC with id
 	 * TSP_HANDLED_S_EL1_INTR. Any other return value
 	 * from the handler will result in panic.
 	 * ------------------------------------------------
 	 */
 	save_eret_context x2 x3
 	bl	tsp_update_sync_sel1_intr_stats
 	bl	tsp_common_int_handler
 	/* Check if the S-EL1 interrupt has been handled */
 	cbnz	x0, tsp_sel1_intr_check_preemption
 	b	tsp_sel1_intr_return
 tsp_sel1_intr_check_preemption:
 	/* Check if the S-EL1 interrupt has been preempted */
 	mov_imm	x1, TSP_PREEMPTED
 	cmp	x0, x1
 	b.ne	tsp_sel1_int_entry_panic
 tsp_sel1_intr_return:
 	mov_imm	x0, TSP_HANDLED_S_EL1_INTR
 	restore_eret_context x2 x3
 	smc	#0

 	/* Should never reach here */
 tsp_sel1_int_entry_panic:
 	bl	plat_panic_handler
 endfunc tsp_sel1_intr_entry

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD when this
 	 * cpu resumes execution after an earlier
 	 * CPU_SUSPEND psci call to ask the TSP to
 	 * restore its saved context. In the current
 	 * implementation, the TSPD saves and restores
 	 * EL1 state so nothing is done here apart from
 	 * acknowledging the request.
 	 * ---------------------------------------------
 	 */
 func tsp_cpu_resume_entry
 	bl	tsp_cpu_resume_main
 	restore_args_call_smc

 	/* Should never reach here */
 	bl	plat_panic_handler
 endfunc tsp_cpu_resume_entry

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD to ask
 	 * the TSP to service a fast smc request.
 	 * ---------------------------------------------
 	 */
 func tsp_fast_smc_entry
 	bl	tsp_smc_handler
 	restore_args_call_smc

 	/* Should never reach here */
 	bl	plat_panic_handler
 endfunc tsp_fast_smc_entry

 	/*---------------------------------------------
 	 * This entrypoint is used by the TSPD to ask
 	 * the TSP to service a std smc request.
 	 * We will enable preemption during execution
 	 * of tsp_smc_handler.
 	 * ---------------------------------------------
 	 */
 func tsp_std_smc_entry
 	msr	daifclr, #DAIF_FIQ_BIT | DAIF_IRQ_BIT
 	bl	tsp_smc_handler
 	msr	daifset, #DAIF_FIQ_BIT | DAIF_IRQ_BIT
 	restore_args_call_smc

 	/* Should never reach here */
 	bl	plat_panic_handler
 endfunc tsp_std_smc_entry
	/*
	* Copyright (c) 2013-2016, ARM Limited and Contributors. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are met:
	*
	* Redistributions of source code must retain the above copyright notice, this
	* list of conditions and the following disclaimer.
	*
	* Redistributions in binary form must reproduce the above copyright notice,
	* this list of conditions and the following disclaimer in the documentation
	* and/or other materials provided with the distribution.
	*
	* Neither the name of ARM nor the names of its contributors may be used
	* to endorse or promote products derived from this software without specific
	* prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
	* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
	* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
	* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
	* POSSIBILITY OF SUCH DAMAGE.
	*/

	#include <arch.h>
	#include <asm_macros.S>
	#include <tsp.h>
	#include <xlat_tables.h>
	#include "../tsp_private.h"


	.globl tsp_entrypoint
	.globl tsp_vector_table



	/* ---------------------------------------------
	* Populate the params in x0-x7 from the pointer
	* to the smc args structure in x0.
	* ---------------------------------------------
	*/
	.macro restore_args_call_smc
	ldp x6, x7, [x0, #TSP_ARG6]
	ldp x4, x5, [x0, #TSP_ARG4]
	ldp x2, x3, [x0, #TSP_ARG2]
	ldp x0, x1, [x0, #TSP_ARG0]
	smc #0
	.endm

	.macro save_eret_context reg1 reg2
	mrs \reg1, elr_el1
	mrs \reg2, spsr_el1
	stp \reg1, \reg2, [sp, #-0x10]!
	stp x30, x18, [sp, #-0x10]!
	.endm

	.macro restore_eret_context reg1 reg2
	ldp x30, x18, [sp], #0x10
	ldp \reg1, \reg2, [sp], #0x10
	msr elr_el1, \reg1
	msr spsr_el1, \reg2
	.endm

	.section .text, "ax"
	.align 3

	func tsp_entrypoint

	/* ---------------------------------------------
	* Set the exception vector to something sane.
	* ---------------------------------------------
	*/
	adr x0, tsp_exceptions
	msr vbar_el1, x0
	isb

	/* ---------------------------------------------
	* Enable the SError interrupt now that the
	* exception vectors have been setup.
	* ---------------------------------------------
	*/
	msr daifclr, #DAIF_ABT_BIT

	/* ---------------------------------------------
	* Enable the instruction cache, stack pointer
	* and data access alignment checks
	* ---------------------------------------------
	*/
	mov x1, #(SCTLR_I_BIT \| SCTLR_A_BIT \| SCTLR_SA_BIT)
	mrs x0, sctlr_el1
	orr x0, x0, x1
	msr sctlr_el1, x0
	isb

	/* ---------------------------------------------
	* Invalidate the RW memory used by the BL32
	* 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.
	* ---------------------------------------------
	*/
	adr x0, __RW_START__
	adr x1, __RW_END__
	sub x1, x1, x0
	bl inv_dcache_range

	/* ---------------------------------------------
	* Zero out NOBITS sections. There are 2 of them:
	* - the .bss section;
	* - the coherent memory section.
	* ---------------------------------------------
	*/
	ldr x0, =__BSS_START__
	ldr x1, =__BSS_SIZE__
	bl zeromem16

	#if USE_COHERENT_MEM
	ldr x0, =__COHERENT_RAM_START__
	ldr x1, =__COHERENT_RAM_UNALIGNED_SIZE__
	bl zeromem16
	#endif

	/* --------------------------------------------
	* 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

	/* ---------------------------------------------
	* Perform early platform setup & platform
	* specific early arch. setup e.g. mmu setup
	* ---------------------------------------------
	*/
	bl tsp_early_platform_setup
	bl tsp_plat_arch_setup

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

	/* ---------------------------------------------
	* Tell TSPD that we are done initialising
	* ---------------------------------------------
	*/
	mov x1, x0
	mov x0, #TSP_ENTRY_DONE
	smc #0

	tsp_entrypoint_panic:
	b tsp_entrypoint_panic
	endfunc tsp_entrypoint


	/* -------------------------------------------
	* Table of entrypoint vectors provided to the
	* TSPD for the various entrypoints
	* -------------------------------------------
	*/
	func tsp_vector_table
	b tsp_std_smc_entry
	b tsp_fast_smc_entry
	b tsp_cpu_on_entry
	b tsp_cpu_off_entry
	b tsp_cpu_resume_entry
	b tsp_cpu_suspend_entry
	b tsp_sel1_intr_entry
	b tsp_system_off_entry
	b tsp_system_reset_entry
	endfunc tsp_vector_table

	/*---------------------------------------------
	* This entrypoint is used by the TSPD when this
	* cpu is to be turned off through a CPU_OFF
	* psci call to ask the TSP to perform any
	* bookeeping necessary. In the current
	* implementation, the TSPD expects the TSP to
	* re-initialise its state so nothing is done
	* here except for acknowledging the request.
	* ---------------------------------------------
	*/
	func tsp_cpu_off_entry
	bl tsp_cpu_off_main
	restore_args_call_smc
	endfunc tsp_cpu_off_entry

	/*---------------------------------------------
	* This entrypoint is used by the TSPD when the
	* system is about to be switched off (through
	* a SYSTEM_OFF psci call) to ask the TSP to
	* perform any necessary bookkeeping.
	* ---------------------------------------------
	*/
	func tsp_system_off_entry
	bl tsp_system_off_main
	restore_args_call_smc
	endfunc tsp_system_off_entry

	/*---------------------------------------------
	* This entrypoint is used by the TSPD when the
	* system is about to be reset (through a
	* SYSTEM_RESET psci call) to ask the TSP to
	* perform any necessary bookkeeping.
	* ---------------------------------------------
	*/
	func tsp_system_reset_entry
	bl tsp_system_reset_main
	restore_args_call_smc
	endfunc tsp_system_reset_entry

	/*---------------------------------------------
	* This entrypoint is used by the TSPD when this
	* cpu is turned on using a CPU_ON psci call to
	* ask the TSP to initialise itself i.e. setup
	* the mmu, stacks etc. Minimal architectural
	* state will be initialised by the TSPD when
	* this function is entered i.e. Caches and MMU
	* will be turned off, the execution state
	* will be aarch64 and exceptions masked.
	* ---------------------------------------------
	*/
	func tsp_cpu_on_entry
	/* ---------------------------------------------
	* Set the exception vector to something sane.
	* ---------------------------------------------
	*/
	adr x0, tsp_exceptions
	msr vbar_el1, x0
	isb

	/* Enable the SError interrupt */
	msr daifclr, #DAIF_ABT_BIT

	/* ---------------------------------------------
	* Enable the instruction cache, stack pointer
	* and data access alignment checks
	* ---------------------------------------------
	*/
	mov x1, #(SCTLR_I_BIT \| SCTLR_A_BIT \| SCTLR_SA_BIT)
	mrs x0, sctlr_el1
	orr x0, x0, x1
	msr sctlr_el1, x0
	isb

	/* --------------------------------------------
	* Give ourselves a stack whose memory will be
	* marked as Normal-IS-WBWA when the MMU is
	* enabled.
	* --------------------------------------------
	*/
	bl plat_set_my_stack

	/* --------------------------------------------
	* Enable the MMU with the DCache disabled. It
	* is safe to use stacks allocated in normal
	* memory as a result. All memory accesses are
	* marked nGnRnE when the MMU is disabled. So
	* all the stack writes will make it to memory.
	* All memory accesses are marked Non-cacheable
	* when the MMU is enabled but D$ is disabled.
	* So used stack memory is guaranteed to be
	* visible immediately after the MMU is enabled
	* Enabling the DCache at the same time as the
	* MMU can lead to speculatively fetched and
	* possibly stale stack memory being read from
	* other caches. This can lead to coherency
	* issues.
	* --------------------------------------------
	*/
	mov x0, #DISABLE_DCACHE
	bl bl32_plat_enable_mmu

	/* ---------------------------------------------
	* Enable the Data cache now that the MMU has
	* been enabled. The stack has been unwound. It
	* will be written first before being read. This
	* will invalidate any stale cache lines resi-
	* -dent in other caches. We assume that
	* interconnect coherency has been enabled for
	* this cluster by EL3 firmware.
	* ---------------------------------------------
	*/
	mrs x0, sctlr_el1
	orr x0, x0, #SCTLR_C_BIT
	msr sctlr_el1, x0
	isb

	/* ---------------------------------------------
	* Enter C runtime to perform any remaining
	* book keeping
	* ---------------------------------------------
	*/
	bl tsp_cpu_on_main
	restore_args_call_smc

	/* Should never reach here */
	tsp_cpu_on_entry_panic:
	b tsp_cpu_on_entry_panic
	endfunc tsp_cpu_on_entry

	/*---------------------------------------------
	* This entrypoint is used by the TSPD when this
	* cpu is to be suspended through a CPU_SUSPEND
	* psci call to ask the TSP to perform any
	* bookeeping necessary. In the current
	* implementation, the TSPD saves and restores
	* the EL1 state.
	* ---------------------------------------------
	*/
	func tsp_cpu_suspend_entry
	bl tsp_cpu_suspend_main
	restore_args_call_smc
	endfunc tsp_cpu_suspend_entry

	/*-------------------------------------------------
	* This entrypoint is used by the TSPD to pass
	* control for `synchronously` handling a S-EL1
	* Interrupt which was triggered while executing
	* in normal world. 'x0' contains a magic number
	* which indicates this. TSPD expects control to
	* be handed back at the end of interrupt
	* processing. This is done through an SMC.
	* The handover agreement is:
	*
	* 1. PSTATE.DAIF are set upon entry. 'x1' has
	* the ELR_EL3 from the non-secure state.
	* 2. TSP has to preserve the callee saved
	* general purpose registers, SP_EL1/EL0 and
	* LR.
	* 3. TSP has to preserve the system and vfp
	* registers (if applicable).
	* 4. TSP can use 'x0-x18' to enable its C
	* runtime.
	* 5. TSP returns to TSPD using an SMC with
	* 'x0' = TSP_HANDLED_S_EL1_INTR
	* ------------------------------------------------
	*/
	func tsp_sel1_intr_entry
	#if DEBUG
	mov_imm x2, TSP_HANDLE_SEL1_INTR_AND_RETURN
	cmp x0, x2
	b.ne tsp_sel1_int_entry_panic
	#endif
	/*-------------------------------------------------
	* Save any previous context needed to perform
	* an exception return from S-EL1 e.g. context
	* from a previous Non secure Interrupt.
	* Update statistics and handle the S-EL1
	* interrupt before returning to the TSPD.
	* IRQ/FIQs are not enabled since that will
	* complicate the implementation. Execution
	* will be transferred back to the normal world
	* in any case. The handler can return 0
	* if the interrupt was handled or TSP_PREEMPTED
	* if the expected interrupt was preempted
	* by an interrupt that should be handled in EL3
	* e.g. Group 0 interrupt in GICv3. In both
	* the cases switch to EL3 using SMC with id
	* TSP_HANDLED_S_EL1_INTR. Any other return value
	* from the handler will result in panic.
	* ------------------------------------------------
	*/
	save_eret_context x2 x3
	bl tsp_update_sync_sel1_intr_stats
	bl tsp_common_int_handler
	/* Check if the S-EL1 interrupt has been handled */
	cbnz x0, tsp_sel1_intr_check_preemption
	b tsp_sel1_intr_return
	tsp_sel1_intr_check_preemption:
	/* Check if the S-EL1 interrupt has been preempted */
	mov_imm x1, TSP_PREEMPTED
	cmp x0, x1
	b.ne tsp_sel1_int_entry_panic
	tsp_sel1_intr_return:
	mov_imm x0, TSP_HANDLED_S_EL1_INTR
	restore_eret_context x2 x3
	smc #0

	/* Should never reach here */
	tsp_sel1_int_entry_panic:
	bl plat_panic_handler
	endfunc tsp_sel1_intr_entry

	/*---------------------------------------------
	* This entrypoint is used by the TSPD when this
	* cpu resumes execution after an earlier
	* CPU_SUSPEND psci call to ask the TSP to
	* restore its saved context. In the current
	* implementation, the TSPD saves and restores
	* EL1 state so nothing is done here apart from
	* acknowledging the request.
	* ---------------------------------------------
	*/
	func tsp_cpu_resume_entry
	bl tsp_cpu_resume_main
	restore_args_call_smc

	/* Should never reach here */
	bl plat_panic_handler
	endfunc tsp_cpu_resume_entry

	/*---------------------------------------------
	* This entrypoint is used by the TSPD to ask
	* the TSP to service a fast smc request.
	* ---------------------------------------------
	*/
	func tsp_fast_smc_entry
	bl tsp_smc_handler
	restore_args_call_smc

	/* Should never reach here */
	bl plat_panic_handler
	endfunc tsp_fast_smc_entry

	/*---------------------------------------------
	* This entrypoint is used by the TSPD to ask
	* the TSP to service a std smc request.
	* We will enable preemption during execution
	* of tsp_smc_handler.
	* ---------------------------------------------
	*/
	func tsp_std_smc_entry
	msr daifclr, #DAIF_FIQ_BIT \| DAIF_IRQ_BIT
	bl tsp_smc_handler
	msr daifset, #DAIF_FIQ_BIT \| DAIF_IRQ_BIT
	restore_args_call_smc

	/* Should never reach here */
	bl plat_panic_handler
	endfunc tsp_std_smc_entry