Multiple cleanups and improvements

- Cleanup exception trigger code
- Cleanup division to divide by 0
- Cleanup SRET code
- Cleanup CSR code
- Added interrupts
- Added TIMER interrupt
master
vhaudiquet 1 year ago
parent a0935f0aad
commit 02114ea7d8
  1. 2
      src/cpu/csr.c
  2. 36
      src/cpu/exception.c
  3. 2
      src/cpu/exception.h
  4. 87
      src/cpu/interrupt.c
  5. 15
      src/cpu/interrupt.h
  6. 42
      src/cpu/rv32cpu.c
  7. 25
      src/main.c
  8. 4
      src/memory/mmu.c

@ -5,7 +5,7 @@ uint32_t csr_read(struct RV32_CPU* cpu, uint32_t csr)
{ {
switch(csr) switch(csr)
{ {
case CSR_TIME: case CSR_CYCLE:
return cpu->sim_ticks_done; return cpu->sim_ticks_done;
break; break;
default: default:

@ -2,7 +2,7 @@
#include <stdio.h> #include <stdio.h>
void exception_trigger(rv32_cpu_t* cpu, uint32_t scause) void exception_trigger(rv32_cpu_t* cpu, uint32_t scause, uint32_t tval)
{ {
// An exception can only be triggered by the CPU itself, // An exception can only be triggered by the CPU itself,
// so we know we already own the mutex // so we know we already own the mutex
@ -12,14 +12,38 @@ void exception_trigger(rv32_cpu_t* cpu, uint32_t scause)
// To achieve that, we can just call cpu_loop (noreturn) // To achieve that, we can just call cpu_loop (noreturn)
// at the end of this function // at the end of this function
// Save execution context, so that 'mret/sret/..' can restore it // Exceptions cannot be disabled
// TODO
// Set PC to STVEC, and set SCAUSE // Set xCAUSE : exception cause, with interrupt bit set to null
// TODO: If PC cannot be mmu_resolved, throw a 'double fault' ?
cpu->pc = cpu->csr[CSR_STVEC];
cpu->csr[CSR_SCAUSE] = scause; cpu->csr[CSR_SCAUSE] = scause;
// Save previous interrupt enable in xSTATUS.xPIE
if(cpu->csr[CSR_SSTATUS] & 0b10U)
cpu->csr[CSR_SSTATUS] |= 0x80;
// Set previous privilege mode in xSTATUS.xPP
// TODO
// Unset SIE (interrupt enable) bit
cpu->csr[CSR_SSTATUS] &= ~0b10U;
// Set privilege mode for exception handling, checking for delegation
// TODO
// Set xTVAL, exception-specific information related to xCAUSE
cpu->csr[CSR_STVAL] = tval;
// Set SEPC to instruction that caused exception
cpu->csr[CSR_SEPC] = cpu->pc;
// Set PC to xTVEC : exception handling code
// xTVEC: [Base(30bits) Mode(2 bits)], address 4-byte aligned in base
// Exceptions are not vectored (we can safely ignore mode)
cpu->pc = cpu->csr[CSR_STVEC] & 0xFFFFFFFC;
// Unlock cpu mutex, cpu_loop will lock it just after
pthread_mutex_unlock(&cpu0_mutex); pthread_mutex_unlock(&cpu0_mutex);
// cpu loop (attribute noreturn should erase previous stack)
cpu_loop(cpu); cpu_loop(cpu);
} }

@ -3,7 +3,7 @@
#include "rv32cpu.h" #include "rv32cpu.h"
void exception_trigger(rv32_cpu_t* cpu, uint32_t scause); void exception_trigger(rv32_cpu_t* cpu, uint32_t scause, uint32_t tval);
#define SCAUSE_INSTRUCTION_MISSALIGNED 0x0 #define SCAUSE_INSTRUCTION_MISSALIGNED 0x0
#define SCAUSE_INSTRUCTION_ACCESS_FAULT 0x1 #define SCAUSE_INSTRUCTION_ACCESS_FAULT 0x1

@ -0,0 +1,87 @@
#include "interrupt.h"
#include "rv32cpu.h"
#include <stdio.h>
#include <unistd.h>
void interrupt_trigger(rv32_cpu_t* cpu, uint32_t scause)
{
// Make sure that interrupts are enabled
if(cpu->privilege_mode == MACHINE)
{
// In machine mode, we check mstatus.sie (bit 1)
if(!(cpu->csr[CSR_MSTATUS] & 0b10))
return;
}
else if(cpu->privilege_mode == SUPERVISOR)
{
// In supervisor mode, we check sstatus.sie (bit 1)
if(!(cpu->csr[CSR_SSTATUS] & 0b10))
return;
}
else
{
// TODO
fprintf(stderr, "interrupt_trigger in non M/S-mode not implemented yet\n");
exit(EXIT_FAILURE);
}
// An interrupt can only be triggered from outside
// of the cpu, so we are on a different thread
// and we don't already own the CPU mutex
// We obtain in this thread the control of the CPU,
// but we know it is not in the middle of an instruction
// (we got the mutex) ; this way we can just change
// registers to set interrupt handler execution
pthread_mutex_lock(&cpu0_mutex);
// Set xCAUSE with interrupt bit set
cpu->csr[CSR_SCAUSE] = 0x80000000 | scause;
// Set xSTATUS.xPIE (previous interrupt enable) bit
cpu->csr[CSR_SSTATUS] |= 0x80;
// Set xSTATUS.xPP (Previous Privilege) bit
// Unset xSTATUS.xIE (interrupt enable) bit
cpu->csr[CSR_SSTATUS] &= ~0b10U;
// Set xEPC : PC at interruption
cpu->csr[CSR_SEPC] = cpu->pc;
// Set PC to xTVEC : exception handler code
// xTVEC: [Base(30bits) Mode(2 bits)], address 4-byte aligned in base
// Interrupts can be vectored, if mode == 1, then pc = xTVEC + scause * 4
int mode = cpu->csr[CSR_STVEC] & 0b11;
switch(mode)
{
case 0:
cpu->pc = cpu->csr[CSR_STVEC] & 0xFFFFFFFC;
break;
case 1:
cpu->pc = (cpu->csr[CSR_STVEC] & 0xFFFFFFFC) + scause * 4;
break;
default:
fprintf(stderr, "interrupt_trigger: invalid mode encountered in sTVEC register\n");
exit(EXIT_FAILURE);
break;
}
pthread_mutex_unlock(&cpu0_mutex);
}
void interrupt_timer_thread()
{
while(1)
{
cpu0->csr[CSR_TIME]++;
interrupt_trigger(cpu0, SCAUSE_SUPERVISOR_TIMER_INTERRUPT);
usleep(1);
}
}
void interrupt_timer_setup()
{
pthread_t timer_thread;
pthread_create(&timer_thread, 0, (void*) interrupt_timer_thread, 0);
}

@ -0,0 +1,15 @@
#ifndef INTERRUPT_H
#define INTERRUPT_H
#include <stdint.h>
#include "rv32cpu.h"
#define SCAUSE_SUPERVISOR_SOFTWARE_INTERRUPT 0x1
#define SCAUSE_SUPERVISOR_TIMER_INTERRUPT 0x5
#define SCAUSE_SUPERVISOR_EXTERNAL_INTERRUPT 0x9
void interrupt_trigger(rv32_cpu_t* cpu, uint32_t scause);
void interrupt_timer_setup();
#endif

@ -49,7 +49,7 @@ void cpu_init()
cpu0->privilege_mode = MACHINE; cpu0->privilege_mode = MACHINE;
} }
static void cpu_decode(raw_instruction_t raw_instruction, instruction_t* output) static void cpu_decode(rv32_cpu_t* cpu, raw_instruction_t raw_instruction, instruction_t* output)
{ {
output->opcode = raw_instruction.opcode; output->opcode = raw_instruction.opcode;
output->immediate = 0; output->immediate = 0;
@ -112,8 +112,8 @@ static void cpu_decode(raw_instruction_t raw_instruction, instruction_t* output)
// TODO : Decode NOP instructions // TODO : Decode NOP instructions
break; break;
default: default:
fprintf(stderr, "Error: Unknown instruction opcode 0x%x, could not decode\n", raw_instruction.opcode); // Throw an 'Invalid OPCODE' exception
exit(EXIT_FAILURE); exception_trigger(cpu, SCAUSE_ILLEGAL_INSTRUCTION, 0);
break; break;
} }
} }
@ -433,6 +433,13 @@ static void cpu_execute(rv32_cpu_t* cpu, instruction_t* instruction)
cpu->regs.x[instruction->rd] = cpu->regs.x[instruction->rs1] ^ cpu->regs.x[instruction->rs2]; cpu->regs.x[instruction->rd] = cpu->regs.x[instruction->rs1] ^ cpu->regs.x[instruction->rs2];
break; break;
case FUNC7_DIV: case FUNC7_DIV:
if(!cpu->regs.x[instruction->rs2])
{
// ISA dictates that we return FFFFFFFF and set a flag bit to signal the exception
cpu->regs.x[instruction->rd] = 0xFFFFFFFF;
// TODO flag ?
break;
}
cpu->regs.x[instruction->rd] = ((int32_t) cpu->regs.x[instruction->rs1]) / ((int32_t) cpu->regs.x[instruction->rs2]); cpu->regs.x[instruction->rd] = ((int32_t) cpu->regs.x[instruction->rs1]) / ((int32_t) cpu->regs.x[instruction->rs2]);
break; break;
default: default:
@ -518,15 +525,30 @@ static void cpu_execute(rv32_cpu_t* cpu, instruction_t* instruction)
break; break;
case IMM_EBREAK: case IMM_EBREAK:
// EBREAK : generate a breakpoint exception // EBREAK : generate a breakpoint exception
exception_trigger(cpu, SCAUSE_BREAKPOINT); exception_trigger(cpu, SCAUSE_BREAKPOINT, 0);
break; break;
case IMM_SRET: case IMM_SRET:
fprintf(stderr, "SRET: We don't support that.\n"); // SRET: Return from supervisor interrupt
// Restore Interrupt Enable from Previous Interrupt Enable
uint32_t sstatus = csr_read(cpu, CSR_SSTATUS);
if(sstatus & 0x80)
csr_write(cpu, CSR_SSTATUS, sstatus | 0b10);
// Restore privilege mode from Previous Privilege
// TODO
// Set Previous Interrupt Enable to 1
csr_write(cpu, CSR_SSTATUS, csr_read(cpu, CSR_SSTATUS) | 0x80);
// Set Previous Privilege to 0
// TODO
// Saved PC before interrupt is in CSR SEPC, jump back
cpu->pc = csr_read(cpu, CSR_SEPC) - 4;
break; break;
case IMM_MRET: case IMM_MRET:
// Ret to destination address : CSR_MEPC content // Ret to destination address : CSR_MEPC content
// Change privilege mode to SUPERVISOR // TODO fix it to act like sret
// TODO : Pop lower-privilege interrupt enable and privilege mode stack
cpu->privilege_mode = SUPERVISOR; cpu->privilege_mode = SUPERVISOR;
cpu->pc = cpu->csr[CSR_MEPC] - 4; cpu->pc = cpu->csr[CSR_MEPC] - 4;
break; break;
@ -537,7 +559,9 @@ static void cpu_execute(rv32_cpu_t* cpu, instruction_t* instruction)
// TODO : Check if we really need to do something on SFENCE.VMA ? // TODO : Check if we really need to do something on SFENCE.VMA ?
break; break;
case FUNC7_WFI: case FUNC7_WFI:
fprintf(stderr, "WFI: Guest kernel must think we have interrupts. We have none. Halting simulation.\n"); // Wait For Interrupt : halt the simulation
// It will be woken up by an interruption
fprintf(stderr, "WFI: Halting simulation.\n");
cpu->sim_ticks_left = 1; cpu->sim_ticks_left = 1;
break; break;
default: default:
@ -712,7 +736,7 @@ __attribute__((noreturn)) void cpu_loop(rv32_cpu_t* cpu)
// Decode // Decode
instruction_t instruction; instruction_t instruction;
cpu_decode(raw_instruction, &instruction); cpu_decode(cpu, raw_instruction, &instruction);
if(trace) if(trace)
{ {

@ -2,6 +2,7 @@
#include "memory/memory.h" #include "memory/memory.h"
#include "bootloader/bootloader.h" #include "bootloader/bootloader.h"
#include "cpu/rv32cpu.h" #include "cpu/rv32cpu.h"
#include "cpu/interrupt.h"
#include "gdbstub/gdbstub.h" #include "gdbstub/gdbstub.h"
#include "devices/uart/uart.h" #include "devices/uart/uart.h"
@ -31,34 +32,20 @@ int main(int argc, char** argv)
gdbstub_wait_for_connection(); gdbstub_wait_for_connection();
} }
// Initialize timer for timer interrupt
interrupt_timer_setup();
// CPU simulation : create cpu0 thread // CPU simulation : create cpu0 thread
if(!gdbstub) cpu0->sim_ticks_left = -1; // Simulate forever if(!gdbstub) cpu0->sim_ticks_left = -1; // Simulate forever
pthread_t cpu0_thread; pthread_t cpu0_thread;
pthread_create(&cpu0_thread, 0, (void*) cpu_loop, cpu0); pthread_create(&cpu0_thread, 0, (void*) cpu_loop, cpu0);
// Wait for the simulation to end // Wait forever, until simulation end (which should be an ecall shutdown)
pthread_join(cpu0_thread, 0);
if(gdbstub) if(gdbstub)
{ {
pthread_join(cpu0_thread, 0);
gdbstub_stop(); gdbstub_stop();
} }
else
{
while(1)
{
pthread_mutex_lock(&cpu0_mutex);
pthread_cond_wait(&cpu0->sim_condition, &cpu0_mutex);
if(!cpu0->sim_ticks_left && cpu0->sim_ticks_done > 0)
{
// Simulation ended
break;
}
pthread_mutex_unlock(&cpu0_mutex);
}
fprintf(stderr, "Simulation ended (in a non-debug environment)\n");
return cpu0->regs.a0;
}
return 0; return 0;
} }

@ -81,7 +81,7 @@ uint32_t mmu_resolve(rv32_cpu_t* cpu, memory_access_type_t access_type, uint32_t
if(!(pte & PTE_V)) if(!(pte & PTE_V))
{ {
// Invalid PTE // Invalid PTE
exception_trigger(cpu, mmu_scause_from_access(access_type)); exception_trigger(cpu, mmu_scause_from_access(access_type), vaddr);
} }
if((pte & PTE_R) || (pte & PTE_W) || (pte & PTE_X)) if((pte & PTE_R) || (pte & PTE_W) || (pte & PTE_X))
@ -109,7 +109,7 @@ uint32_t mmu_resolve(rv32_cpu_t* cpu, memory_access_type_t access_type, uint32_t
if(!(pte & PTE_V)) if(!(pte & PTE_V))
{ {
// Invalid PTE // Invalid PTE
exception_trigger(cpu, mmu_scause_from_access(access_type)); exception_trigger(cpu, mmu_scause_from_access(access_type), vaddr);
} }
// This must be a leaf PTE, as Sv32 only supports 2-level mappings // This must be a leaf PTE, as Sv32 only supports 2-level mappings

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