esp-idf/components/riscv/vectors.S
Omar Chebib 220e52fca1 RISC-V: Fix vectors.S assembly file indentation and macro usage
The file is now more consistent as the macros have been fixed, more comments
have been added and the indentation is now using spaces only.
2021-11-15 17:17:24 +08:00

285 lines
8.9 KiB
ArmAsm

/*
* SPDX-FileCopyrightText: 2017-2021 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#include "soc/soc.h"
#include "soc/interrupt_reg.h"
#include "riscv/rvruntime-frames.h"
#include "soc/soc_caps.h"
#include "sdkconfig.h"
.equ SAVE_REGS, 32
.equ CONTEXT_SIZE, (SAVE_REGS * 4)
.equ panic_from_exception, xt_unhandled_exception
.equ panic_from_isr, panicHandler
/* Macro which first allocates space on the stack to save general
* purpose registers, and then save them. GP register is excluded.
* The default size allocated on the stack is CONTEXT_SIZE, but it
* can be overridden. */
.macro save_general_regs cxt_size=CONTEXT_SIZE
addi sp, sp, -\cxt_size
sw ra, RV_STK_RA(sp)
sw tp, RV_STK_TP(sp)
sw t0, RV_STK_T0(sp)
sw t1, RV_STK_T1(sp)
sw t2, RV_STK_T2(sp)
sw s0, RV_STK_S0(sp)
sw s1, RV_STK_S1(sp)
sw a0, RV_STK_A0(sp)
sw a1, RV_STK_A1(sp)
sw a2, RV_STK_A2(sp)
sw a3, RV_STK_A3(sp)
sw a4, RV_STK_A4(sp)
sw a5, RV_STK_A5(sp)
sw a6, RV_STK_A6(sp)
sw a7, RV_STK_A7(sp)
sw s2, RV_STK_S2(sp)
sw s3, RV_STK_S3(sp)
sw s4, RV_STK_S4(sp)
sw s5, RV_STK_S5(sp)
sw s6, RV_STK_S6(sp)
sw s7, RV_STK_S7(sp)
sw s8, RV_STK_S8(sp)
sw s9, RV_STK_S9(sp)
sw s10, RV_STK_S10(sp)
sw s11, RV_STK_S11(sp)
sw t3, RV_STK_T3(sp)
sw t4, RV_STK_T4(sp)
sw t5, RV_STK_T5(sp)
sw t6, RV_STK_T6(sp)
.endm
.macro save_mepc
csrr t0, mepc
sw t0, RV_STK_MEPC(sp)
.endm
/* Restore the general purpose registers (excluding gp) from the context on
* the stack. The context is then deallocated. The default size is CONTEXT_SIZE
* but it can be overriden. */
.macro restore_general_regs cxt_size=CONTEXT_SIZE
lw ra, RV_STK_RA(sp)
lw tp, RV_STK_TP(sp)
lw t0, RV_STK_T0(sp)
lw t1, RV_STK_T1(sp)
lw t2, RV_STK_T2(sp)
lw s0, RV_STK_S0(sp)
lw s1, RV_STK_S1(sp)
lw a0, RV_STK_A0(sp)
lw a1, RV_STK_A1(sp)
lw a2, RV_STK_A2(sp)
lw a3, RV_STK_A3(sp)
lw a4, RV_STK_A4(sp)
lw a5, RV_STK_A5(sp)
lw a6, RV_STK_A6(sp)
lw a7, RV_STK_A7(sp)
lw s2, RV_STK_S2(sp)
lw s3, RV_STK_S3(sp)
lw s4, RV_STK_S4(sp)
lw s5, RV_STK_S5(sp)
lw s6, RV_STK_S6(sp)
lw s7, RV_STK_S7(sp)
lw s8, RV_STK_S8(sp)
lw s9, RV_STK_S9(sp)
lw s10, RV_STK_S10(sp)
lw s11, RV_STK_S11(sp)
lw t3, RV_STK_T3(sp)
lw t4, RV_STK_T4(sp)
lw t5, RV_STK_T5(sp)
lw t6, RV_STK_T6(sp)
addi sp,sp, \cxt_size
.endm
.macro restore_mepc
lw t0, RV_STK_MEPC(sp)
csrw mepc, t0
.endm
.global rtos_int_enter
.global rtos_int_exit
.global _global_interrupt_handler
.section .exception_vectors.text
/* This is the vector table. MTVEC points here.
*
* Use 4-byte intructions here. 1 instruction = 1 entry of the table.
* The CPU jumps to MTVEC (i.e. the first entry) in case of an exception,
* and (MTVEC & 0xfffffffc) + (mcause & 0x7fffffff) * 4, in case of an interrupt.
*
* Note: for our CPU, we need to place this on a 256-byte boundary, as CPU
* only uses the 24 MSBs of the MTVEC, i.e. (MTVEC & 0xffffff00).
*/
.balign 0x100
.global _vector_table
.type _vector_table, @function
_vector_table:
.option push
.option norvc
j _panic_handler /* exception handler, entry 0 */
.rept (ETS_T1_WDT_INUM - 1)
j _interrupt_handler /* 24 identical entries, all pointing to the interrupt handler */
.endr
j _panic_handler /* Call panic handler for ETS_T1_WDT_INUM interrupt (soc-level panic)*/
j _panic_handler /* Call panic handler for ETS_CACHEERR_INUM interrupt (soc-level panic)*/
#ifdef CONFIG_ESP_SYSTEM_MEMPROT_FEATURE
j _panic_handler /* Call panic handler for ETS_MEMPROT_ERR_INUM interrupt (soc-level panic)*/
.rept (ETS_MAX_INUM - ETS_MEMPROT_ERR_INUM)
#else
.rept (ETS_MAX_INUM - ETS_CACHEERR_INUM)
#endif //CONFIG_ESP_SYSTEM_MEMPROT_FEATURE
j _interrupt_handler /* 6 identical entries, all pointing to the interrupt handler */
.endr
.option pop
.size _vector_table, .-_vector_table
/* Exception handler.*/
.type _panic_handler, @function
_panic_handler:
/* Allocate space on the stack and store general purpose registers */
save_general_regs RV_STK_FRMSZ
/* As gp register is not saved by the macro, save it here */
sw gp, RV_STK_GP(sp)
/* Same goes for the SP value before trapping */
addi t0, sp, RV_STK_FRMSZ /* restore sp with the value when trap happened */
/* Save CSRs */
sw t0, RV_STK_SP(sp)
csrr t0, mepc
sw t0, RV_STK_MEPC(sp)
csrr t0, mstatus
sw t0, RV_STK_MSTATUS(sp)
csrr t0, mtvec
sw t0, RV_STK_MTVEC(sp)
csrr t0, mtval
sw t0, RV_STK_MTVAL(sp)
csrr t0, mhartid
sw t0, RV_STK_MHARTID(sp)
/* Call panic_from_exception(sp) or panic_from_isr(sp)
* depending on whether we have a pseudo excause or not.
* If mcause's highest bit is 1, then an interrupt called this routine,
* so we have a pseudo excause. Else, it is due to a exception, we don't
* have an pseudo excause */
mv a0, sp
csrr a1, mcause
/* Branches instructions don't accept immediates values, so use t1 to
* store our comparator */
li t0, 0x80000000
bgeu a1, t0, _call_panic_handler
sw a1, RV_STK_MCAUSE(sp)
/* exception_from_panic never returns */
j panic_from_exception
_call_panic_handler:
/* Remove highest bit from mcause (a1) register and save it in the
* structure */
not t0, t0
and a1, a1, t0
sw a1, RV_STK_MCAUSE(sp)
/* exception_from_isr never returns */
j panic_from_isr
.size panic_from_isr, .-panic_from_isr
/* This is the interrupt handler.
* It saves the registers on the stack,
* prepares for interrupt nesting,
* re-enables the interrupts,
* then jumps to the C dispatcher in interrupt.c.
*/
.global _interrupt_handler
.type _interrupt_handler, @function
_interrupt_handler:
/* Start by saving the general purpose registers and the PC value before
* the interrupt happened. */
save_general_regs
save_mepc
/* Before doing anythig preserve the stack pointer */
/* It will be saved in current TCB, if needed */
mv a0, sp
call rtos_int_enter
/* If this is a non-nested interrupt, SP now points to the interrupt stack */
/* Before dispatch c handler, restore interrupt to enable nested intr */
csrr s1, mcause
csrr s2, mstatus
/* Save the interrupt threshold level */
la t0, INTERRUPT_CORE0_CPU_INT_THRESH_REG
lw s3, 0(t0)
/* Increase interrupt threshold level */
li t2, 0x7fffffff
and t1, s1, t2 /* t1 = mcause & mask */
slli t1, t1, 2 /* t1 = mcause * 4 */
la t2, INTC_INT_PRIO_REG(0)
add t1, t2, t1 /* t1 = INTC_INT_PRIO_REG + 4 * mcause */
lw t2, 0(t1) /* t2 = INTC_INT_PRIO_REG[mcause] */
addi t2, t2, 1 /* t2 = t2 +1 */
sw t2, 0(t0) /* INTERRUPT_CORE0_CPU_INT_THRESH_REG = t2 */
fence
li t0, 0x8
csrrs t0, mstatus, t0
/* MIE set. Nested interrupts can now occur */
#ifdef CONFIG_PM_TRACE
li a0, 0 /* = ESP_PM_TRACE_IDLE */
#if SOC_CPU_CORES_NUM == 1
li a1, 0 /* No need to check core ID on single core hardware */
#else
csrr a1, mhartid
#endif
la t0, esp_pm_trace_exit
jalr t0 /* absolute jump, avoid the 1 MiB range constraint */
#endif
#ifdef CONFIG_PM_ENABLE
la t0, esp_pm_impl_isr_hook
jalr t0 /* absolute jump, avoid the 1 MiB range constraint */
#endif
/* call the C dispatcher */
mv a0, sp /* argument 1, stack pointer */
mv a1, s1 /* argument 2, interrupt number (mcause) */
/* mask off the interrupt flag of mcause */
li t0, 0x7fffffff
and a1, a1, t0
jal _global_interrupt_handler
/* After dispatch c handler, disable interrupt to make freertos make context switch */
li t0, 0x8
csrrc t0, mstatus, t0
/* MIE cleared. Nested interrupts are disabled */
/* restore the interrupt threshold level */
la t0, INTERRUPT_CORE0_CPU_INT_THRESH_REG
sw s3, 0(t0)
fence
/* Yield to the next task is needed: */
mv a0, sp
call rtos_int_exit
/* If this is a non-nested interrupt, context switch called, SP now points to back to task stack. */
/* The next (or current) stack pointer is returned in a0 */
mv sp, a0
/* restore the rest of the registers */
csrw mcause, s1
csrw mstatus, s2
restore_mepc
restore_general_regs
/* exit, this will also re-enable the interrupts */
mret
.size _interrupt_handler, .-_interrupt_handler