211 lines
4.6 KiB
C
211 lines
4.6 KiB
C
#include "types.h"
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#include "param.h"
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#include "memlayout.h"
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#include "riscv.h"
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#include "spinlock.h"
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#include "proc.h"
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#include "defs.h"
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struct spinlock tickslock;
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uint ticks;
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extern char trampout[], trampin[];
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// in kernelvec.S, calls kerneltrap().
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void kernelvec();
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extern int devintr();
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void
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trapinit(void)
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{
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initlock(&tickslock, "time");
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}
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// set up to take exceptions and traps while in the kernel.
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void
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trapinithart(void)
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{
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w_stvec((uint64)kernelvec);
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}
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//
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// handle an interrupt, exception, or system call from user space.
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// called from trampoline.S
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//
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void
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usertrap(void)
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{
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int which_dev = 0;
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if((r_sstatus() & SSTATUS_SPP) != 0)
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panic("usertrap: not from user mode");
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// send interrupts and exceptions to kerneltrap(),
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// since we're now in the kernel.
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w_stvec((uint64)kernelvec);
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struct proc *p = myproc();
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// save user program counter.
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p->tf->epc = r_sepc();
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if(r_scause() == 8){
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// system call
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if(p->killed)
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exit();
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// sepc points to the ecall instruction,
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// but we want to return to the next instruction.
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p->tf->epc += 4;
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// an interrupt will change sstatus &c registers,
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// so don't enable until done with those registers.
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intr_on();
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syscall();
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} else if((which_dev = devintr()) != 0){
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// ok
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} else {
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printf("usertrap(): unexpected scause %p pid=%d\n", r_scause(), p->pid);
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printf(" sepc=%p stval=%p\n", r_sepc(), r_stval());
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p->killed = 1;
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}
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if(p->killed)
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exit();
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// give up the CPU if this is a timer interrupt.
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if(which_dev == 2)
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yield();
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usertrapret();
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}
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//
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// return to user space
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//
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void
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usertrapret(void)
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{
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struct proc *p = myproc();
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// turn off interrupts, since we're switching
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// now from kerneltrap() to usertrap().
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intr_off();
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// send interrupts and exceptions to trampoline.S
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w_stvec(TRAMPOLINE + (trampin - trampout));
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// set up values that trampoline.S will need when
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// the process next re-enters the kernel.
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p->tf->kernel_satp = r_satp();
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p->tf->kernel_sp = p->kstack + PGSIZE;
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p->tf->kernel_trap = (uint64)usertrap;
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p->tf->kernel_hartid = r_tp();
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// set up the registers that trampoline.S's sret will use
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// to get to user space.
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// set S Previous Privilege mode to User.
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unsigned long x = r_sstatus();
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x &= ~SSTATUS_SPP; // clear SPP to 0 for user mode
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x |= SSTATUS_SPIE; // enable interrupts in user mode
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w_sstatus(x);
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// set S Exception Program Counter to the saved user pc.
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w_sepc(p->tf->epc);
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// tell trampline.S the user page table to switch to.
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uint64 satp = MAKE_SATP(p->pagetable);
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// jump to trampoline.S at the top of memory, which
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// switches to the user page table, restores user registers,
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// and switches to user mode with sret.
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((void (*)(uint64,uint64))TRAMPOLINE)(TRAPFRAME, satp);
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}
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// interrupts and exceptions from kernel code go here via kernelvec,
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// on whatever the current kernel stack is.
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// must be 4-byte aligned to fit in stvec.
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void
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kerneltrap()
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{
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int which_dev = 0;
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uint64 sepc = r_sepc();
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uint64 sstatus = r_sstatus();
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uint64 scause = r_scause();
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if((sstatus & SSTATUS_SPP) == 0)
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panic("kerneltrap: not from supervisor mode");
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if(intr_get() != 0)
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panic("kerneltrap: interrupts enabled");
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if((which_dev = devintr()) == 0){
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printf("scause %p\n", scause);
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printf("sepc=%p stval=%p\n", r_sepc(), r_stval());
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panic("kerneltrap");
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}
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// give up the CPU if this is a timer interrupt.
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if(which_dev == 2 && myproc() != 0 && myproc()->state == RUNNING)
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yield();
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// the yield() may have caused some traps to occur,
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// so restore trap registers for use by kernelvec.S's sepc instruction.
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w_sepc(sepc);
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w_sstatus(sstatus);
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}
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void
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clockintr()
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{
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acquire(&tickslock);
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ticks++;
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wakeup(&ticks);
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release(&tickslock);
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}
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// check if it's an external interrupt or software interrupt,
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// and handle it.
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// returns 2 if timer interrupt,
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// 1 if other device,
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// 0 if not recognized.
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int
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devintr()
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{
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uint64 scause = r_scause();
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if((scause & 0x8000000000000000L) &&
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(scause & 0xff) == 9){
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// supervisor external interrupt, via PLIC.
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int irq = plic_claim();
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if(irq == UART0_IRQ){
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uartintr();
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} else if(irq == VIRTIO0_IRQ){
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virtio_disk_intr();
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}
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plic_complete(irq);
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return 1;
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} else if(scause == 0x8000000000000001){
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// software interrupt from a machine-mode timer interrupt,
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// forwarded by machinevec in kernelvec.S.
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if(cpuid() == 0){
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clockintr();
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}
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// acknowledge the software interrupt by clearing
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// the SSIP bit in sip.
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w_sip(r_sip() & ~2);
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return 2;
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} else {
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return 0;
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}
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}
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