riscv-pke/kernel/strap_vector.S

59 lines
1.8 KiB
ArmAsm

.section trapsec
.globl trap_sec_start
trap_sec_start:
#include "util/load_store.S"
#
# When a trap (e.g., a syscall from User mode in this lab) happens and the computer
# enters the Supervisor mode, the computer will continue to execute the following
# function (smode_trap_vector) to actually handle the trap.
#
# NOTE: sscratch points to the trapframe of current process before entering
# smode_trap_vector. It is done by reture_to_user function (defined below) when
# scheduling a user-mode application to run.
#
.globl smode_trap_vector
.align 4
smode_trap_vector:
# swap a0 and sscratch, so that points a0 to the trapframe of current process
csrrw a0, sscratch, a0
# save the context (user registers) of current process in its trapframe.
addi t6, a0 , 0
store_all_registers
# come back to save a0 register before entering trap handling in trapframe
csrr t0, sscratch
sd t0, 72(a0)
# use the "user kernel" stack (whose pointer stored in p->trapframe->kernel_sp)
ld sp, 248(a0)
# load the address of smode_trap_handler() from p->trapframe->kernel_trap
ld t0, 256(a0)
# jump to smode_trap_handler() that is defined in kernel/trap.c
jr t0
#
# return from Supervisor mode to User mode, transition is made by using a trapframe,
# which stores the context of a user application.
# return_to_user() takes one parameter, i.e., the pointer (a0 register) pointing to a
# trapframe (defined in kernel/process.h) of the process.
#
.globl return_to_user
return_to_user:
# save a0 in sscratch, so sscratch points to a trapframe now.
csrw sscratch, a0
# let [t6]=[a0]
addi t6, a0, 0
# restore all registers from trapframe, so as to resort the execution of a process
restore_all_registers
# return to user mode and user pc.
sret