arch/riscv/kernel/entry.S - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-only */
 /*
  * Copyright (C) 2012 Regents of the University of California
  * Copyright (C) 2017 SiFive
  */

 #include <linux/init.h>
 #include <linux/linkage.h>

 #include <asm/asm.h>
 #include <asm/csr.h>
 #include <asm/unistd.h>
 #include <asm/thread_info.h>
 #include <asm/asm-offsets.h>
 #include <asm/errata_list.h>

 SYM_CODE_START(handle_exception)
 	/*
 	 * If coming from userspace, preserve the user thread pointer and load
 	 * the kernel thread pointer.  If we came from the kernel, the scratch
 	 * register will contain 0, and we should continue on the current TP.
 	 */
 	csrrw tp, CSR_SCRATCH, tp
 	bnez tp, _save_context

 _restore_kernel_tpsp:
 	csrr tp, CSR_SCRATCH
 	REG_S sp, TASK_TI_KERNEL_SP(tp)

 #ifdef CONFIG_VMAP_STACK
 	addi sp, sp, -(PT_SIZE_ON_STACK)
 	srli sp, sp, THREAD_SHIFT
 	andi sp, sp, 0x1
 	bnez sp, handle_kernel_stack_overflow
 	REG_L sp, TASK_TI_KERNEL_SP(tp)
 #endif

 _save_context:
 	REG_S sp, TASK_TI_USER_SP(tp)
 	REG_L sp, TASK_TI_KERNEL_SP(tp)
 	addi sp, sp, -(PT_SIZE_ON_STACK)
 	REG_S x1,  PT_RA(sp)
 	REG_S x3,  PT_GP(sp)
 	REG_S x5,  PT_T0(sp)
 	save_from_x6_to_x31

 	/*
 	 * Disable user-mode memory access as it should only be set in the
 	 * actual user copy routines.
 	 *
 	 * Disable the FPU to detect illegal usage of floating point in kernel
 	 * space.
 	 */
 	li t0, SR_SUM | SR_FS

 	REG_L s0, TASK_TI_USER_SP(tp)
 	csrrc s1, CSR_STATUS, t0
 	csrr s2, CSR_EPC
 	csrr s3, CSR_TVAL
 	csrr s4, CSR_CAUSE
 	csrr s5, CSR_SCRATCH
 	REG_S s0, PT_SP(sp)
 	REG_S s1, PT_STATUS(sp)
 	REG_S s2, PT_EPC(sp)
 	REG_S s3, PT_BADADDR(sp)
 	REG_S s4, PT_CAUSE(sp)
 	REG_S s5, PT_TP(sp)

 	/*
 	 * Set the scratch register to 0, so that if a recursive exception
 	 * occurs, the exception vector knows it came from the kernel
 	 */
 	csrw CSR_SCRATCH, x0

 	/* Load the global pointer */
 .option push
 .option norelax
 	la gp, __global_pointer$
 .option pop
 	move a0, sp /* pt_regs */
 	la ra, ret_from_exception

 	/*
 	 * MSB of cause differentiates between
 	 * interrupts and exceptions
 	 */
 	bge s4, zero, 1f

 	/* Handle interrupts */
 	tail do_irq
 1:
 	/* Handle other exceptions */
 	slli t0, s4, RISCV_LGPTR
 	la t1, excp_vect_table
 	la t2, excp_vect_table_end
 	add t0, t1, t0
 	/* Check if exception code lies within bounds */
 	bgeu t0, t2, 1f
 	REG_L t0, 0(t0)
 	jr t0
 1:
 	tail do_trap_unknown
 SYM_CODE_END(handle_exception)

 /*
  * The ret_from_exception must be called with interrupt disabled. Here is the
  * caller list:
  *  - handle_exception
  *  - ret_from_fork
  */
 SYM_CODE_START_NOALIGN(ret_from_exception)
 	REG_L s0, PT_STATUS(sp)
 #ifdef CONFIG_RISCV_M_MODE
 	/* the MPP value is too large to be used as an immediate arg for addi */
 	li t0, SR_MPP
 	and s0, s0, t0
 #else
 	andi s0, s0, SR_SPP
 #endif
 	bnez s0, 1f

 	/* Save unwound kernel stack pointer in thread_info */
 	addi s0, sp, PT_SIZE_ON_STACK
 	REG_S s0, TASK_TI_KERNEL_SP(tp)

 	/*
 	 * Save TP into the scratch register , so we can find the kernel data
 	 * structures again.
 	 */
 	csrw CSR_SCRATCH, tp
 1:
 	REG_L a0, PT_STATUS(sp)
 	/*
 	 * The current load reservation is effectively part of the processor's
 	 * state, in the sense that load reservations cannot be shared between
 	 * different hart contexts.  We can't actually save and restore a load
 	 * reservation, so instead here we clear any existing reservation --
 	 * it's always legal for implementations to clear load reservations at
 	 * any point (as long as the forward progress guarantee is kept, but
 	 * we'll ignore that here).
 	 *
 	 * Dangling load reservations can be the result of taking a trap in the
 	 * middle of an LR/SC sequence, but can also be the result of a taken
 	 * forward branch around an SC -- which is how we implement CAS.  As a
 	 * result we need to clear reservations between the last CAS and the
 	 * jump back to the new context.  While it is unlikely the store
 	 * completes, implementations are allowed to expand reservations to be
 	 * arbitrarily large.
 	 */
 	REG_L  a2, PT_EPC(sp)
 	REG_SC x0, a2, PT_EPC(sp)

 	csrw CSR_STATUS, a0
 	csrw CSR_EPC, a2

 	REG_L x1,  PT_RA(sp)
 	REG_L x3,  PT_GP(sp)
 	REG_L x4,  PT_TP(sp)
 	REG_L x5,  PT_T0(sp)
 	restore_from_x6_to_x31

 	REG_L x2,  PT_SP(sp)

 #ifdef CONFIG_RISCV_M_MODE
 	mret
 #else
 	sret
 #endif
 SYM_CODE_END(ret_from_exception)

 #ifdef CONFIG_VMAP_STACK
 SYM_CODE_START_LOCAL(handle_kernel_stack_overflow)
 	/*
 	 * Takes the psuedo-spinlock for the shadow stack, in case multiple
 	 * harts are concurrently overflowing their kernel stacks.  We could
 	 * store any value here, but since we're overflowing the kernel stack
 	 * already we only have SP to use as a scratch register.  So we just
 	 * swap in the address of the spinlock, as that's definately non-zero.
 	 *
 	 * Pairs with a store_release in handle_bad_stack().
 	 */
 1:	la sp, spin_shadow_stack
 	REG_AMOSWAP_AQ sp, sp, (sp)
 	bnez sp, 1b

 	la sp, shadow_stack
 	addi sp, sp, SHADOW_OVERFLOW_STACK_SIZE

 	//save caller register to shadow stack
 	addi sp, sp, -(PT_SIZE_ON_STACK)
 	REG_S x1,  PT_RA(sp)
 	REG_S x5,  PT_T0(sp)
 	REG_S x6,  PT_T1(sp)
 	REG_S x7,  PT_T2(sp)
 	REG_S x10, PT_A0(sp)
 	REG_S x11, PT_A1(sp)
 	REG_S x12, PT_A2(sp)
 	REG_S x13, PT_A3(sp)
 	REG_S x14, PT_A4(sp)
 	REG_S x15, PT_A5(sp)
 	REG_S x16, PT_A6(sp)
 	REG_S x17, PT_A7(sp)
 	REG_S x28, PT_T3(sp)
 	REG_S x29, PT_T4(sp)
 	REG_S x30, PT_T5(sp)
 	REG_S x31, PT_T6(sp)

 	la ra, restore_caller_reg
 	tail get_overflow_stack

 restore_caller_reg:
 	//save per-cpu overflow stack
 	REG_S a0, -8(sp)
 	//restore caller register from shadow_stack
 	REG_L x1,  PT_RA(sp)
 	REG_L x5,  PT_T0(sp)
 	REG_L x6,  PT_T1(sp)
 	REG_L x7,  PT_T2(sp)
 	REG_L x10, PT_A0(sp)
 	REG_L x11, PT_A1(sp)
 	REG_L x12, PT_A2(sp)
 	REG_L x13, PT_A3(sp)
 	REG_L x14, PT_A4(sp)
 	REG_L x15, PT_A5(sp)
 	REG_L x16, PT_A6(sp)
 	REG_L x17, PT_A7(sp)
 	REG_L x28, PT_T3(sp)
 	REG_L x29, PT_T4(sp)
 	REG_L x30, PT_T5(sp)
 	REG_L x31, PT_T6(sp)

 	//load per-cpu overflow stack
 	REG_L sp, -8(sp)
 	addi sp, sp, -(PT_SIZE_ON_STACK)

 	//save context to overflow stack
 	REG_S x1,  PT_RA(sp)
 	REG_S x3,  PT_GP(sp)
 	REG_S x5,  PT_T0(sp)
 	save_from_x6_to_x31

 	REG_L s0, TASK_TI_KERNEL_SP(tp)
 	csrr s1, CSR_STATUS
 	csrr s2, CSR_EPC
 	csrr s3, CSR_TVAL
 	csrr s4, CSR_CAUSE
 	csrr s5, CSR_SCRATCH
 	REG_S s0, PT_SP(sp)
 	REG_S s1, PT_STATUS(sp)
 	REG_S s2, PT_EPC(sp)
 	REG_S s3, PT_BADADDR(sp)
 	REG_S s4, PT_CAUSE(sp)
 	REG_S s5, PT_TP(sp)
 	move a0, sp
 	tail handle_bad_stack
 SYM_CODE_END(handle_kernel_stack_overflow)
 #endif

 SYM_CODE_START(ret_from_fork)
 	call schedule_tail
 	beqz s0, 1f	/* not from kernel thread */
 	/* Call fn(arg) */
 	move a0, s1
 	jalr s0
 1:
 	move a0, sp /* pt_regs */
 	la ra, ret_from_exception
 	tail syscall_exit_to_user_mode
 SYM_CODE_END(ret_from_fork)

 /*
  * Integer register context switch
  * The callee-saved registers must be saved and restored.
  *
  *   a0: previous task_struct (must be preserved across the switch)
  *   a1: next task_struct
  *
  * The value of a0 and a1 must be preserved by this function, as that's how
  * arguments are passed to schedule_tail.
  */
 SYM_FUNC_START(__switch_to)
 	/* Save context into prev->thread */
 	li    a4,  TASK_THREAD_RA
 	add   a3, a0, a4
 	add   a4, a1, a4
 	REG_S ra,  TASK_THREAD_RA_RA(a3)
 	REG_S sp,  TASK_THREAD_SP_RA(a3)
 	REG_S s0,  TASK_THREAD_S0_RA(a3)
 	REG_S s1,  TASK_THREAD_S1_RA(a3)
 	REG_S s2,  TASK_THREAD_S2_RA(a3)
 	REG_S s3,  TASK_THREAD_S3_RA(a3)
 	REG_S s4,  TASK_THREAD_S4_RA(a3)
 	REG_S s5,  TASK_THREAD_S5_RA(a3)
 	REG_S s6,  TASK_THREAD_S6_RA(a3)
 	REG_S s7,  TASK_THREAD_S7_RA(a3)
 	REG_S s8,  TASK_THREAD_S8_RA(a3)
 	REG_S s9,  TASK_THREAD_S9_RA(a3)
 	REG_S s10, TASK_THREAD_S10_RA(a3)
 	REG_S s11, TASK_THREAD_S11_RA(a3)
 	/* Restore context from next->thread */
 	REG_L ra,  TASK_THREAD_RA_RA(a4)
 	REG_L sp,  TASK_THREAD_SP_RA(a4)
 	REG_L s0,  TASK_THREAD_S0_RA(a4)
 	REG_L s1,  TASK_THREAD_S1_RA(a4)
 	REG_L s2,  TASK_THREAD_S2_RA(a4)
 	REG_L s3,  TASK_THREAD_S3_RA(a4)
 	REG_L s4,  TASK_THREAD_S4_RA(a4)
 	REG_L s5,  TASK_THREAD_S5_RA(a4)
 	REG_L s6,  TASK_THREAD_S6_RA(a4)
 	REG_L s7,  TASK_THREAD_S7_RA(a4)
 	REG_L s8,  TASK_THREAD_S8_RA(a4)
 	REG_L s9,  TASK_THREAD_S9_RA(a4)
 	REG_L s10, TASK_THREAD_S10_RA(a4)
 	REG_L s11, TASK_THREAD_S11_RA(a4)
 	/* The offset of thread_info in task_struct is zero. */
 	move tp, a1
 	ret
 SYM_FUNC_END(__switch_to)

 #ifndef CONFIG_MMU
 #define do_page_fault do_trap_unknown
 #endif

 	.section ".rodata"
 	.align LGREG
 	/* Exception vector table */
 SYM_CODE_START(excp_vect_table)
 	RISCV_PTR do_trap_insn_misaligned
 	ALT_INSN_FAULT(RISCV_PTR do_trap_insn_fault)
 	RISCV_PTR do_trap_insn_illegal
 	RISCV_PTR do_trap_break
 	RISCV_PTR do_trap_load_misaligned
 	RISCV_PTR do_trap_load_fault
 	RISCV_PTR do_trap_store_misaligned
 	RISCV_PTR do_trap_store_fault
 	RISCV_PTR do_trap_ecall_u /* system call */
 	RISCV_PTR do_trap_ecall_s
 	RISCV_PTR do_trap_unknown
 	RISCV_PTR do_trap_ecall_m
 	/* instruciton page fault */
 	ALT_PAGE_FAULT(RISCV_PTR do_page_fault)
 	RISCV_PTR do_page_fault   /* load page fault */
 	RISCV_PTR do_trap_unknown
 	RISCV_PTR do_page_fault   /* store page fault */
 excp_vect_table_end:
 SYM_CODE_END(excp_vect_table)

 #ifndef CONFIG_MMU
 SYM_CODE_START(__user_rt_sigreturn)
 	li a7, __NR_rt_sigreturn
 	scall
 SYM_CODE_END(__user_rt_sigreturn)
 #endif
	/* SPDX-License-Identifier: GPL-2.0-only */
	/*
	* Copyright (C) 2012 Regents of the University of California
	* Copyright (C) 2017 SiFive
	*/

	#include <linux/init.h>
	#include <linux/linkage.h>

	#include <asm/asm.h>
	#include <asm/csr.h>
	#include <asm/unistd.h>
	#include <asm/thread_info.h>
	#include <asm/asm-offsets.h>
	#include <asm/errata_list.h>

	SYM_CODE_START(handle_exception)
	/*
	* If coming from userspace, preserve the user thread pointer and load
	* the kernel thread pointer. If we came from the kernel, the scratch
	* register will contain 0, and we should continue on the current TP.
	*/
	csrrw tp, CSR_SCRATCH, tp
	bnez tp, _save_context

	_restore_kernel_tpsp:
	csrr tp, CSR_SCRATCH
	REG_S sp, TASK_TI_KERNEL_SP(tp)

	#ifdef CONFIG_VMAP_STACK
	addi sp, sp, -(PT_SIZE_ON_STACK)
	srli sp, sp, THREAD_SHIFT
	andi sp, sp, 0x1
	bnez sp, handle_kernel_stack_overflow
	REG_L sp, TASK_TI_KERNEL_SP(tp)
	#endif

	_save_context:
	REG_S sp, TASK_TI_USER_SP(tp)
	REG_L sp, TASK_TI_KERNEL_SP(tp)
	addi sp, sp, -(PT_SIZE_ON_STACK)
	REG_S x1, PT_RA(sp)
	REG_S x3, PT_GP(sp)
	REG_S x5, PT_T0(sp)
	save_from_x6_to_x31

	/*
	* Disable user-mode memory access as it should only be set in the
	* actual user copy routines.
	*
	* Disable the FPU to detect illegal usage of floating point in kernel
	* space.
	*/
	li t0, SR_SUM \| SR_FS

	REG_L s0, TASK_TI_USER_SP(tp)
	csrrc s1, CSR_STATUS, t0
	csrr s2, CSR_EPC
	csrr s3, CSR_TVAL
	csrr s4, CSR_CAUSE
	csrr s5, CSR_SCRATCH
	REG_S s0, PT_SP(sp)
	REG_S s1, PT_STATUS(sp)
	REG_S s2, PT_EPC(sp)
	REG_S s3, PT_BADADDR(sp)
	REG_S s4, PT_CAUSE(sp)
	REG_S s5, PT_TP(sp)

	/*
	* Set the scratch register to 0, so that if a recursive exception
	* occurs, the exception vector knows it came from the kernel
	*/
	csrw CSR_SCRATCH, x0

	/* Load the global pointer */
	.option push
	.option norelax
	la gp, __global_pointer$
	.option pop
	move a0, sp /* pt_regs */
	la ra, ret_from_exception

	/*
	* MSB of cause differentiates between
	* interrupts and exceptions
	*/
	bge s4, zero, 1f

	/* Handle interrupts */
	tail do_irq
	1:
	/* Handle other exceptions */
	slli t0, s4, RISCV_LGPTR
	la t1, excp_vect_table
	la t2, excp_vect_table_end
	add t0, t1, t0
	/* Check if exception code lies within bounds */
	bgeu t0, t2, 1f
	REG_L t0, 0(t0)
	jr t0
	1:
	tail do_trap_unknown
	SYM_CODE_END(handle_exception)

	/*
	* The ret_from_exception must be called with interrupt disabled. Here is the
	* caller list:
	* - handle_exception
	* - ret_from_fork
	*/
	SYM_CODE_START_NOALIGN(ret_from_exception)
	REG_L s0, PT_STATUS(sp)
	#ifdef CONFIG_RISCV_M_MODE
	/* the MPP value is too large to be used as an immediate arg for addi */
	li t0, SR_MPP
	and s0, s0, t0
	#else
	andi s0, s0, SR_SPP
	#endif
	bnez s0, 1f

	/* Save unwound kernel stack pointer in thread_info */
	addi s0, sp, PT_SIZE_ON_STACK
	REG_S s0, TASK_TI_KERNEL_SP(tp)

	/*
	* Save TP into the scratch register , so we can find the kernel data
	* structures again.
	*/
	csrw CSR_SCRATCH, tp
	1:
	REG_L a0, PT_STATUS(sp)
	/*
	* The current load reservation is effectively part of the processor's
	* state, in the sense that load reservations cannot be shared between
	* different hart contexts. We can't actually save and restore a load
	* reservation, so instead here we clear any existing reservation --
	* it's always legal for implementations to clear load reservations at
	* any point (as long as the forward progress guarantee is kept, but
	* we'll ignore that here).
	*
	* Dangling load reservations can be the result of taking a trap in the
	* middle of an LR/SC sequence, but can also be the result of a taken
	* forward branch around an SC -- which is how we implement CAS. As a
	* result we need to clear reservations between the last CAS and the
	* jump back to the new context. While it is unlikely the store
	* completes, implementations are allowed to expand reservations to be
	* arbitrarily large.
	*/
	REG_L a2, PT_EPC(sp)
	REG_SC x0, a2, PT_EPC(sp)

	csrw CSR_STATUS, a0
	csrw CSR_EPC, a2

	REG_L x1, PT_RA(sp)
	REG_L x3, PT_GP(sp)
	REG_L x4, PT_TP(sp)
	REG_L x5, PT_T0(sp)
	restore_from_x6_to_x31

	REG_L x2, PT_SP(sp)

	#ifdef CONFIG_RISCV_M_MODE
	mret
	#else
	sret
	#endif
	SYM_CODE_END(ret_from_exception)

	#ifdef CONFIG_VMAP_STACK
	SYM_CODE_START_LOCAL(handle_kernel_stack_overflow)
	/*
	* Takes the psuedo-spinlock for the shadow stack, in case multiple
	* harts are concurrently overflowing their kernel stacks. We could
	* store any value here, but since we're overflowing the kernel stack
	* already we only have SP to use as a scratch register. So we just
	* swap in the address of the spinlock, as that's definately non-zero.
	*
	* Pairs with a store_release in handle_bad_stack().
	*/
	1: la sp, spin_shadow_stack
	REG_AMOSWAP_AQ sp, sp, (sp)
	bnez sp, 1b

	la sp, shadow_stack
	addi sp, sp, SHADOW_OVERFLOW_STACK_SIZE

	//save caller register to shadow stack
	addi sp, sp, -(PT_SIZE_ON_STACK)
	REG_S x1, PT_RA(sp)
	REG_S x5, PT_T0(sp)
	REG_S x6, PT_T1(sp)
	REG_S x7, PT_T2(sp)
	REG_S x10, PT_A0(sp)
	REG_S x11, PT_A1(sp)
	REG_S x12, PT_A2(sp)
	REG_S x13, PT_A3(sp)
	REG_S x14, PT_A4(sp)
	REG_S x15, PT_A5(sp)
	REG_S x16, PT_A6(sp)
	REG_S x17, PT_A7(sp)
	REG_S x28, PT_T3(sp)
	REG_S x29, PT_T4(sp)
	REG_S x30, PT_T5(sp)
	REG_S x31, PT_T6(sp)

	la ra, restore_caller_reg
	tail get_overflow_stack

	restore_caller_reg:
	//save per-cpu overflow stack
	REG_S a0, -8(sp)
	//restore caller register from shadow_stack
	REG_L x1, PT_RA(sp)
	REG_L x5, PT_T0(sp)
	REG_L x6, PT_T1(sp)
	REG_L x7, PT_T2(sp)
	REG_L x10, PT_A0(sp)
	REG_L x11, PT_A1(sp)
	REG_L x12, PT_A2(sp)
	REG_L x13, PT_A3(sp)
	REG_L x14, PT_A4(sp)
	REG_L x15, PT_A5(sp)
	REG_L x16, PT_A6(sp)
	REG_L x17, PT_A7(sp)
	REG_L x28, PT_T3(sp)
	REG_L x29, PT_T4(sp)
	REG_L x30, PT_T5(sp)
	REG_L x31, PT_T6(sp)

	//load per-cpu overflow stack
	REG_L sp, -8(sp)
	addi sp, sp, -(PT_SIZE_ON_STACK)

	//save context to overflow stack
	REG_S x1, PT_RA(sp)
	REG_S x3, PT_GP(sp)
	REG_S x5, PT_T0(sp)
	save_from_x6_to_x31

	REG_L s0, TASK_TI_KERNEL_SP(tp)
	csrr s1, CSR_STATUS
	csrr s2, CSR_EPC
	csrr s3, CSR_TVAL
	csrr s4, CSR_CAUSE
	csrr s5, CSR_SCRATCH
	REG_S s0, PT_SP(sp)
	REG_S s1, PT_STATUS(sp)
	REG_S s2, PT_EPC(sp)
	REG_S s3, PT_BADADDR(sp)
	REG_S s4, PT_CAUSE(sp)
	REG_S s5, PT_TP(sp)
	move a0, sp
	tail handle_bad_stack
	SYM_CODE_END(handle_kernel_stack_overflow)
	#endif

	SYM_CODE_START(ret_from_fork)
	call schedule_tail
	beqz s0, 1f /* not from kernel thread */
	/* Call fn(arg) */
	move a0, s1
	jalr s0
	1:
	move a0, sp /* pt_regs */
	la ra, ret_from_exception
	tail syscall_exit_to_user_mode
	SYM_CODE_END(ret_from_fork)

	/*
	* Integer register context switch
	* The callee-saved registers must be saved and restored.
	*
	* a0: previous task_struct (must be preserved across the switch)
	* a1: next task_struct
	*
	* The value of a0 and a1 must be preserved by this function, as that's how
	* arguments are passed to schedule_tail.
	*/
	SYM_FUNC_START(__switch_to)
	/* Save context into prev->thread */
	li a4, TASK_THREAD_RA
	add a3, a0, a4
	add a4, a1, a4
	REG_S ra, TASK_THREAD_RA_RA(a3)
	REG_S sp, TASK_THREAD_SP_RA(a3)
	REG_S s0, TASK_THREAD_S0_RA(a3)
	REG_S s1, TASK_THREAD_S1_RA(a3)
	REG_S s2, TASK_THREAD_S2_RA(a3)
	REG_S s3, TASK_THREAD_S3_RA(a3)
	REG_S s4, TASK_THREAD_S4_RA(a3)
	REG_S s5, TASK_THREAD_S5_RA(a3)
	REG_S s6, TASK_THREAD_S6_RA(a3)
	REG_S s7, TASK_THREAD_S7_RA(a3)
	REG_S s8, TASK_THREAD_S8_RA(a3)
	REG_S s9, TASK_THREAD_S9_RA(a3)
	REG_S s10, TASK_THREAD_S10_RA(a3)
	REG_S s11, TASK_THREAD_S11_RA(a3)
	/* Restore context from next->thread */
	REG_L ra, TASK_THREAD_RA_RA(a4)
	REG_L sp, TASK_THREAD_SP_RA(a4)
	REG_L s0, TASK_THREAD_S0_RA(a4)
	REG_L s1, TASK_THREAD_S1_RA(a4)
	REG_L s2, TASK_THREAD_S2_RA(a4)
	REG_L s3, TASK_THREAD_S3_RA(a4)
	REG_L s4, TASK_THREAD_S4_RA(a4)
	REG_L s5, TASK_THREAD_S5_RA(a4)
	REG_L s6, TASK_THREAD_S6_RA(a4)
	REG_L s7, TASK_THREAD_S7_RA(a4)
	REG_L s8, TASK_THREAD_S8_RA(a4)
	REG_L s9, TASK_THREAD_S9_RA(a4)
	REG_L s10, TASK_THREAD_S10_RA(a4)
	REG_L s11, TASK_THREAD_S11_RA(a4)
	/* The offset of thread_info in task_struct is zero. */
	move tp, a1
	ret
	SYM_FUNC_END(__switch_to)

	#ifndef CONFIG_MMU
	#define do_page_fault do_trap_unknown
	#endif

	.section ".rodata"
	.align LGREG
	/* Exception vector table */
	SYM_CODE_START(excp_vect_table)
	RISCV_PTR do_trap_insn_misaligned
	ALT_INSN_FAULT(RISCV_PTR do_trap_insn_fault)
	RISCV_PTR do_trap_insn_illegal
	RISCV_PTR do_trap_break
	RISCV_PTR do_trap_load_misaligned
	RISCV_PTR do_trap_load_fault
	RISCV_PTR do_trap_store_misaligned
	RISCV_PTR do_trap_store_fault
	RISCV_PTR do_trap_ecall_u /* system call */
	RISCV_PTR do_trap_ecall_s
	RISCV_PTR do_trap_unknown
	RISCV_PTR do_trap_ecall_m
	/* instruciton page fault */
	ALT_PAGE_FAULT(RISCV_PTR do_page_fault)
	RISCV_PTR do_page_fault /* load page fault */
	RISCV_PTR do_trap_unknown
	RISCV_PTR do_page_fault /* store page fault */
	excp_vect_table_end:
	SYM_CODE_END(excp_vect_table)

	#ifndef CONFIG_MMU
	SYM_CODE_START(__user_rt_sigreturn)
	li a7, __NR_rt_sigreturn
	scall
	SYM_CODE_END(__user_rt_sigreturn)
	#endif