arch/nios2/core/exception.S - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2016 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/toolchain.h>
 #include <zephyr/linker/sections.h>
 #include <offsets_short.h>

 /* exports */
 GTEXT(_exception)

 /* import */
 GTEXT(_Fault)
 GTEXT(arch_swap)
 #ifdef CONFIG_IRQ_OFFLOAD
 GTEXT(z_irq_do_offload)
 GTEXT(_offload_routine)
 #endif

 /* Allows use of r1/at register, otherwise reserved for assembler use */
 .set noat

 /* Placed into special 'exception' section so that the linker can put this code
  * at ALT_CPU_EXCEPTION_ADDR defined in system.h
  *
  * This is the common entry point for processor exceptions and interrupts from
  * the Internal Interrupt Controller (IIC).
  *
  * If the External (EIC) controller is in use, then we will never get here on
  * behalf of an interrupt, instead the EIC driver will have set up a vector
  * table and the processor will jump directly into the appropriate table
  * entry.
  */
 SECTION_FUNC(exception.entry, _exception)
 	/* Reserve thread stack space for saving context */
 	subi sp, sp, __z_arch_esf_t_SIZEOF

 	/* Preserve all caller-saved registers onto the thread's stack */
 	stw ra,  __z_arch_esf_t_ra_OFFSET(sp)
 	stw r1,  __z_arch_esf_t_r1_OFFSET(sp)
 	stw r2,  __z_arch_esf_t_r2_OFFSET(sp)
 	stw r3,  __z_arch_esf_t_r3_OFFSET(sp)
 	stw r4,  __z_arch_esf_t_r4_OFFSET(sp)
 	stw r5,  __z_arch_esf_t_r5_OFFSET(sp)
 	stw r6,  __z_arch_esf_t_r6_OFFSET(sp)
 	stw r7,  __z_arch_esf_t_r7_OFFSET(sp)
 	stw r8,  __z_arch_esf_t_r8_OFFSET(sp)
 	stw r9,  __z_arch_esf_t_r9_OFFSET(sp)
 	stw r10, __z_arch_esf_t_r10_OFFSET(sp)
 	stw r11, __z_arch_esf_t_r11_OFFSET(sp)
 	stw r12, __z_arch_esf_t_r12_OFFSET(sp)
 	stw r13, __z_arch_esf_t_r13_OFFSET(sp)
 	stw r14, __z_arch_esf_t_r14_OFFSET(sp)
 	stw r15, __z_arch_esf_t_r15_OFFSET(sp)

 	/* Store value of estatus control register */
 	rdctl et, estatus
 	stw   et, __z_arch_esf_t_estatus_OFFSET(sp)

 	/* ea-4 is the address of the instruction when the exception happened,
 	 * put this in the stack frame as well
 	 */
 	addi  r15, ea, -4
 	stw   r15, __z_arch_esf_t_instr_OFFSET(sp)

 	/* Figure out whether we are here because of an interrupt or an
 	 * exception. If an interrupt, switch stacks and enter IRQ handling
 	 * code. If an exception, remain on current stack and enter exception
 	 * handing code. From the CPU manual, ipending must be nonzero and
 	 * estatis.PIE must be enabled for this to be considered an interrupt.
 	 *
 	 * Stick ipending in r4 since it will be an arg for _enter_irq
 	 */
 	rdctl r4, ipending
 	beq   r4, zero, not_interrupt
 	/* We stashed estatus in et earlier */
 	andi  r15, et, 1
 	beq   r15, zero, not_interrupt

 is_interrupt:
 	/* If we get here, this is an interrupt */

 	/* Grab a reference to _kernel in r10 so we can determine the
 	 * current irq stack pointer
 	 */
 	movhi r10, %hi(_kernel)
 	ori r10, r10, %lo(_kernel)

 	/* Stash a copy of thread's sp in r12 so that we can put it on the IRQ
 	 * stack
 	 */
 	mov r12, sp

 	/* Switch to interrupt stack */
 	ldw sp, _kernel_offset_to_irq_stack(r10)

 	/* Store thread stack pointer onto IRQ stack */
 	addi sp, sp, -4
 	stw r12, 0(sp)

 on_irq_stack:

 	/* Enter C interrupt handling code. Value of ipending will be the
 	 * function parameter since we put it in r4
 	 */
 	call _enter_irq

 	/* Interrupt handler finished and the interrupt should be serviced
 	 * now, the appropriate bits in ipending should be cleared */

 	/* Get a reference to _kernel again in r10 */
 	movhi r10, %hi(_kernel)
 	ori   r10, r10, %lo(_kernel)

 #ifdef CONFIG_PREEMPT_ENABLED
 	ldw   r11, _kernel_offset_to_current(r10)
 	/* Determine whether the exception of the ISR requires context
 	 * switch
 	 */

 	/* Call into the kernel to see if a scheduling decision is necessary */
 	ldw  r2, _kernel_offset_to_ready_q_cache(r10)
 	beq  r2, r11, no_reschedule

 	/*
 	 * A context reschedule is required: keep the volatile registers of
 	 * the interrupted thread on the context's stack.  Utilize
 	 * the existing arch_swap() primitive to save the remaining
 	 * thread's registers (including floating point) and perform
 	 * a switch to the new thread.
 	 */

 	/* We put the thread stack pointer on top of the IRQ stack before
 	 * we switched stacks. Restore it to go back to thread stack
 	 */
 	ldw sp, 0(sp)

 	/* Argument to Swap() is estatus since that's the state of the
 	 * status register before the exception happened. When coming
 	 * out of the context switch we need this info to restore
 	 * IRQ lock state. We put this value in et earlier.
 	 */
 	mov r4, et

 	call arch_swap
 	jmpi _exception_exit
 #else
 	jmpi no_reschedule
 #endif /* CONFIG_PREEMPT_ENABLED */

 not_interrupt:

 	/* Since this wasn't an interrupt we're not going to restart the
 	 * faulting instruction.
 	 *
 	 * We earlier put ea - 4 in the stack frame, replace it with just ea
 	 */
 	stw ea, __z_arch_esf_t_instr_OFFSET(sp)

 #ifdef CONFIG_IRQ_OFFLOAD
 	/* Check the contents of _offload_routine. If non-NULL, jump into
 	 * the interrupt code anyway.
 	 */
 	movhi r10, %hi(_offload_routine)
 	ori   r10, r10, %lo(_offload_routine)
 	ldw   r11, (r10)
 	bne   r11, zero, is_interrupt
 #endif

 _exception_enter_fault:
 	/* If we get here, the exception wasn't in interrupt or an
 	 * invocation of irq_oflload(). Let _Fault() handle it in
 	 * C domain
 	 */

 	mov  r4, sp
 	call _Fault
 	jmpi _exception_exit

 no_reschedule:

 	/* We put the thread stack pointer on top of the IRQ stack before
 	 * we switched stacks. Restore it to go back to thread stack
 	 */
 	ldw sp, 0(sp)

 	/* Fall through */

 _exception_exit:
 	/* We are on the thread stack. Restore all saved registers
 	 * and return to the interrupted context */

 	/* Return address from the exception */
 	ldw ea, __z_arch_esf_t_instr_OFFSET(sp)

 	/* Restore estatus
 	 * XXX is this right??? */
 	ldw   r5, __z_arch_esf_t_estatus_OFFSET(sp)
 	wrctl estatus, r5

 	/* Restore caller-saved registers */
 	ldw ra,  __z_arch_esf_t_ra_OFFSET(sp)
 	ldw r1,  __z_arch_esf_t_r1_OFFSET(sp)
 	ldw r2,  __z_arch_esf_t_r2_OFFSET(sp)
 	ldw r3,  __z_arch_esf_t_r3_OFFSET(sp)
 	ldw r4,  __z_arch_esf_t_r4_OFFSET(sp)
 	ldw r5,  __z_arch_esf_t_r5_OFFSET(sp)
 	ldw r6,  __z_arch_esf_t_r6_OFFSET(sp)
 	ldw r7,  __z_arch_esf_t_r7_OFFSET(sp)
 	ldw r8,  __z_arch_esf_t_r8_OFFSET(sp)
 	ldw r9,  __z_arch_esf_t_r9_OFFSET(sp)
 	ldw r10, __z_arch_esf_t_r10_OFFSET(sp)
 	ldw r11, __z_arch_esf_t_r11_OFFSET(sp)
 	ldw r12, __z_arch_esf_t_r12_OFFSET(sp)
 	ldw r13, __z_arch_esf_t_r13_OFFSET(sp)
 	ldw r14, __z_arch_esf_t_r14_OFFSET(sp)
 	ldw r15, __z_arch_esf_t_r15_OFFSET(sp)

 	/* Put the stack pointer back where it was when we entered
 	 * exception state
 	 */
 	addi sp, sp, __z_arch_esf_t_SIZEOF

 	/* All done, copy estatus into status and transfer to ea */
 	eret
	/*
	* Copyright (c) 2016 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/toolchain.h>
	#include <zephyr/linker/sections.h>
	#include <offsets_short.h>

	/* exports */
	GTEXT(_exception)

	/* import */
	GTEXT(_Fault)
	GTEXT(arch_swap)
	#ifdef CONFIG_IRQ_OFFLOAD
	GTEXT(z_irq_do_offload)
	GTEXT(_offload_routine)
	#endif

	/* Allows use of r1/at register, otherwise reserved for assembler use */
	.set noat

	/* Placed into special 'exception' section so that the linker can put this code
	* at ALT_CPU_EXCEPTION_ADDR defined in system.h
	*
	* This is the common entry point for processor exceptions and interrupts from
	* the Internal Interrupt Controller (IIC).
	*
	* If the External (EIC) controller is in use, then we will never get here on
	* behalf of an interrupt, instead the EIC driver will have set up a vector
	* table and the processor will jump directly into the appropriate table
	* entry.
	*/
	SECTION_FUNC(exception.entry, _exception)
	/* Reserve thread stack space for saving context */
	subi sp, sp, __z_arch_esf_t_SIZEOF

	/* Preserve all caller-saved registers onto the thread's stack */
	stw ra, __z_arch_esf_t_ra_OFFSET(sp)
	stw r1, __z_arch_esf_t_r1_OFFSET(sp)
	stw r2, __z_arch_esf_t_r2_OFFSET(sp)
	stw r3, __z_arch_esf_t_r3_OFFSET(sp)
	stw r4, __z_arch_esf_t_r4_OFFSET(sp)
	stw r5, __z_arch_esf_t_r5_OFFSET(sp)
	stw r6, __z_arch_esf_t_r6_OFFSET(sp)
	stw r7, __z_arch_esf_t_r7_OFFSET(sp)
	stw r8, __z_arch_esf_t_r8_OFFSET(sp)
	stw r9, __z_arch_esf_t_r9_OFFSET(sp)
	stw r10, __z_arch_esf_t_r10_OFFSET(sp)
	stw r11, __z_arch_esf_t_r11_OFFSET(sp)
	stw r12, __z_arch_esf_t_r12_OFFSET(sp)
	stw r13, __z_arch_esf_t_r13_OFFSET(sp)
	stw r14, __z_arch_esf_t_r14_OFFSET(sp)
	stw r15, __z_arch_esf_t_r15_OFFSET(sp)

	/* Store value of estatus control register */
	rdctl et, estatus
	stw et, __z_arch_esf_t_estatus_OFFSET(sp)

	/* ea-4 is the address of the instruction when the exception happened,
	* put this in the stack frame as well
	*/
	addi r15, ea, -4
	stw r15, __z_arch_esf_t_instr_OFFSET(sp)

	/* Figure out whether we are here because of an interrupt or an
	* exception. If an interrupt, switch stacks and enter IRQ handling
	* code. If an exception, remain on current stack and enter exception
	* handing code. From the CPU manual, ipending must be nonzero and
	* estatis.PIE must be enabled for this to be considered an interrupt.
	*
	* Stick ipending in r4 since it will be an arg for _enter_irq
	*/
	rdctl r4, ipending
	beq r4, zero, not_interrupt
	/* We stashed estatus in et earlier */
	andi r15, et, 1
	beq r15, zero, not_interrupt

	is_interrupt:
	/* If we get here, this is an interrupt */

	/* Grab a reference to _kernel in r10 so we can determine the
	* current irq stack pointer
	*/
	movhi r10, %hi(_kernel)
	ori r10, r10, %lo(_kernel)

	/* Stash a copy of thread's sp in r12 so that we can put it on the IRQ
	* stack
	*/
	mov r12, sp

	/* Switch to interrupt stack */
	ldw sp, _kernel_offset_to_irq_stack(r10)

	/* Store thread stack pointer onto IRQ stack */
	addi sp, sp, -4
	stw r12, 0(sp)

	on_irq_stack:

	/* Enter C interrupt handling code. Value of ipending will be the
	* function parameter since we put it in r4
	*/
	call _enter_irq

	/* Interrupt handler finished and the interrupt should be serviced
	* now, the appropriate bits in ipending should be cleared */

	/* Get a reference to _kernel again in r10 */
	movhi r10, %hi(_kernel)
	ori r10, r10, %lo(_kernel)

	#ifdef CONFIG_PREEMPT_ENABLED
	ldw r11, _kernel_offset_to_current(r10)
	/* Determine whether the exception of the ISR requires context
	* switch
	*/

	/* Call into the kernel to see if a scheduling decision is necessary */
	ldw r2, _kernel_offset_to_ready_q_cache(r10)
	beq r2, r11, no_reschedule

	/*
	* A context reschedule is required: keep the volatile registers of
	* the interrupted thread on the context's stack. Utilize
	* the existing arch_swap() primitive to save the remaining
	* thread's registers (including floating point) and perform
	* a switch to the new thread.
	*/

	/* We put the thread stack pointer on top of the IRQ stack before
	* we switched stacks. Restore it to go back to thread stack
	*/
	ldw sp, 0(sp)

	/* Argument to Swap() is estatus since that's the state of the
	* status register before the exception happened. When coming
	* out of the context switch we need this info to restore
	* IRQ lock state. We put this value in et earlier.
	*/
	mov r4, et

	call arch_swap
	jmpi _exception_exit
	#else
	jmpi no_reschedule
	#endif /* CONFIG_PREEMPT_ENABLED */

	not_interrupt:

	/* Since this wasn't an interrupt we're not going to restart the
	* faulting instruction.
	*
	* We earlier put ea - 4 in the stack frame, replace it with just ea
	*/
	stw ea, __z_arch_esf_t_instr_OFFSET(sp)

	#ifdef CONFIG_IRQ_OFFLOAD
	/* Check the contents of _offload_routine. If non-NULL, jump into
	* the interrupt code anyway.
	*/
	movhi r10, %hi(_offload_routine)
	ori r10, r10, %lo(_offload_routine)
	ldw r11, (r10)
	bne r11, zero, is_interrupt
	#endif

	_exception_enter_fault:
	/* If we get here, the exception wasn't in interrupt or an
	* invocation of irq_oflload(). Let _Fault() handle it in
	* C domain
	*/

	mov r4, sp
	call _Fault
	jmpi _exception_exit

	no_reschedule:

	/* We put the thread stack pointer on top of the IRQ stack before
	* we switched stacks. Restore it to go back to thread stack
	*/
	ldw sp, 0(sp)

	/* Fall through */

	_exception_exit:
	/* We are on the thread stack. Restore all saved registers
	* and return to the interrupted context */

	/* Return address from the exception */
	ldw ea, __z_arch_esf_t_instr_OFFSET(sp)

	/* Restore estatus
	* XXX is this right??? */
	ldw r5, __z_arch_esf_t_estatus_OFFSET(sp)
	wrctl estatus, r5

	/* Restore caller-saved registers */
	ldw ra, __z_arch_esf_t_ra_OFFSET(sp)
	ldw r1, __z_arch_esf_t_r1_OFFSET(sp)
	ldw r2, __z_arch_esf_t_r2_OFFSET(sp)
	ldw r3, __z_arch_esf_t_r3_OFFSET(sp)
	ldw r4, __z_arch_esf_t_r4_OFFSET(sp)
	ldw r5, __z_arch_esf_t_r5_OFFSET(sp)
	ldw r6, __z_arch_esf_t_r6_OFFSET(sp)
	ldw r7, __z_arch_esf_t_r7_OFFSET(sp)
	ldw r8, __z_arch_esf_t_r8_OFFSET(sp)
	ldw r9, __z_arch_esf_t_r9_OFFSET(sp)
	ldw r10, __z_arch_esf_t_r10_OFFSET(sp)
	ldw r11, __z_arch_esf_t_r11_OFFSET(sp)
	ldw r12, __z_arch_esf_t_r12_OFFSET(sp)
	ldw r13, __z_arch_esf_t_r13_OFFSET(sp)
	ldw r14, __z_arch_esf_t_r14_OFFSET(sp)
	ldw r15, __z_arch_esf_t_r15_OFFSET(sp)

	/* Put the stack pointer back where it was when we entered
	* exception state
	*/
	addi sp, sp, __z_arch_esf_t_SIZEOF

	/* All done, copy estatus into status and transfer to ea */
	eret