/* * Copyright (c) 2006-2022, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2022-12-08 RT-Thread first version */ #include #include #include #include #include "mmu.h" #include "encoding.h" #include "stack.h" #include "sbi.h" #include "riscv.h" #include "interrupt.h" #include "plic.h" #include "tick.h" #ifdef RT_USING_SMART #include #else #define rt_hw_backtrace(...) (0) #endif #define DBG_TAG "libcpu.trap" #define DBG_LVL DBG_INFO #include void dump_regs(struct rt_hw_stack_frame *regs) { rt_kprintf("--------------Dump Registers-----------------\n"); rt_kprintf("Function Registers:\n"); rt_kprintf("\tra(x1) = 0x%p\tuser_sp = 0x%p\n", regs->ra, regs->user_sp_exc_stack); rt_kprintf("\tgp(x3) = 0x%p\ttp(x4) = 0x%p\n", regs->gp, regs->tp); rt_kprintf("Temporary Registers:\n"); rt_kprintf("\tt0(x5) = 0x%p\tt1(x6) = 0x%p\n", regs->t0, regs->t1); rt_kprintf("\tt2(x7) = 0x%p\n", regs->t2); rt_kprintf("\tt3(x28) = 0x%p\tt4(x29) = 0x%p\n", regs->t3, regs->t4); rt_kprintf("\tt5(x30) = 0x%p\tt6(x31) = 0x%p\n", regs->t5, regs->t6); rt_kprintf("Saved Registers:\n"); rt_kprintf("\ts0/fp(x8) = 0x%p\ts1(x9) = 0x%p\n", regs->s0_fp, regs->s1); rt_kprintf("\ts2(x18) = 0x%p\ts3(x19) = 0x%p\n", regs->s2, regs->s3); rt_kprintf("\ts4(x20) = 0x%p\ts5(x21) = 0x%p\n", regs->s4, regs->s5); rt_kprintf("\ts6(x22) = 0x%p\ts7(x23) = 0x%p\n", regs->s6, regs->s7); rt_kprintf("\ts8(x24) = 0x%p\ts9(x25) = 0x%p\n", regs->s8, regs->s9); rt_kprintf("\ts10(x26) = 0x%p\ts11(x27) = 0x%p\n", regs->s10, regs->s11); rt_kprintf("Function Arguments Registers:\n"); rt_kprintf("\ta0(x10) = 0x%p\ta1(x11) = 0x%p\n", regs->a0, regs->a1); rt_kprintf("\ta2(x12) = 0x%p\ta3(x13) = 0x%p\n", regs->a2, regs->a3); rt_kprintf("\ta4(x14) = 0x%p\ta5(x15) = 0x%p\n", regs->a4, regs->a5); rt_kprintf("\ta6(x16) = 0x%p\ta7(x17) = 0x%p\n", regs->a6, regs->a7); rt_kprintf("sstatus = 0x%p\n", regs->sstatus); rt_kprintf("\t%s\n", (regs->sstatus & SSTATUS_SIE) ? "Supervisor Interrupt Enabled" : "Supervisor Interrupt Disabled"); rt_kprintf("\t%s\n", (regs->sstatus & SSTATUS_SPIE) ? "Last Time Supervisor Interrupt Enabled" : "Last Time Supervisor Interrupt Disabled"); rt_kprintf("\t%s\n", (regs->sstatus & SSTATUS_SPP) ? "Last Privilege is Supervisor Mode" : "Last Privilege is User Mode"); rt_kprintf("\t%s\n", (regs->sstatus & SSTATUS_SUM) ? "Permit to Access User Page" : "Not Permit to Access User Page"); rt_kprintf("\t%s\n", (regs->sstatus & (1 << 19)) ? "Permit to Read Executable-only Page" : "Not Permit to Read Executable-only Page"); rt_size_t satp_v = read_csr(satp); rt_kprintf("satp = 0x%p\n", satp_v); rt_kprintf("\tCurrent Page Table(Physical) = 0x%p\n", __MASKVALUE(satp_v, __MASK(44)) << PAGE_OFFSET_BIT); rt_kprintf("\tCurrent ASID = 0x%p\n", __MASKVALUE(satp_v >> 44, __MASK(16)) << PAGE_OFFSET_BIT); const char *mode_str = "Unknown Address Translation/Protection Mode"; switch (__MASKVALUE(satp_v >> 60, __MASK(4))) { case 0: mode_str = "No Address Translation/Protection Mode"; break; case 8: mode_str = "Page-based 39-bit Virtual Addressing Mode"; break; case 9: mode_str = "Page-based 48-bit Virtual Addressing Mode"; break; } rt_kprintf("\tMode = %s\n", mode_str); rt_kprintf("-----------------Dump OK---------------------\n"); } static const char *Exception_Name[] = { "Instruction Address Misaligned", "Instruction Access Fault", "Illegal Instruction", "Breakpoint", "Load Address Misaligned", "Load Access Fault", "Store/AMO Address Misaligned", "Store/AMO Access Fault", "Environment call from U-mode", "Environment call from S-mode", "Reserved-10", "Reserved-11", "Instruction Page Fault", "Load Page Fault", "Reserved-14", "Store/AMO Page Fault"}; static const char *Interrupt_Name[] = { "User Software Interrupt", "Supervisor Software Interrupt", "Reversed-2", "Reversed-3", "User Timer Interrupt", "Supervisor Timer Interrupt", "Reversed-6", "Reversed-7", "User External Interrupt", "Supervisor External Interrupt", "Reserved-10", "Reserved-11", }; extern struct rt_irq_desc irq_desc[]; #ifndef RT_USING_SMP static volatile int nested = 0; #define ENTER_TRAP \ nested += 1 #define EXIT_TRAP \ nested -= 1 #define CHECK_NESTED_PANIC(cause, tval, epc, eframe) \ if (nested != 1) \ handle_nested_trap_panic(cause, tval, epc, eframe) #endif /* RT_USING_SMP */ static const char *get_exception_msg(int id) { const char *msg; if (id < sizeof(Exception_Name) / sizeof(const char *)) { msg = Exception_Name[id]; } else { msg = "Unknown Exception"; } return msg; } #ifdef RT_USING_SMART void handle_user(rt_size_t scause, rt_size_t stval, rt_size_t sepc, struct rt_hw_stack_frame *sp) { rt_size_t id = __MASKVALUE(scause, __MASK(63UL)); /* user page fault */ enum rt_mm_fault_op fault_op; enum rt_mm_fault_type fault_type; switch (id) { case EP_LOAD_PAGE_FAULT: fault_op = MM_FAULT_OP_READ; fault_type = MM_FAULT_TYPE_PAGE_FAULT; break; case EP_LOAD_ACCESS_FAULT: fault_op = MM_FAULT_OP_READ; fault_type = MM_FAULT_TYPE_ACCESS_FAULT; break; case EP_LOAD_ADDRESS_MISALIGNED: fault_op = MM_FAULT_OP_READ; fault_type = MM_FAULT_TYPE_BUS_ERROR; break; case EP_STORE_PAGE_FAULT: fault_op = MM_FAULT_OP_WRITE; fault_type = MM_FAULT_TYPE_PAGE_FAULT; break; case EP_STORE_ACCESS_FAULT: fault_op = MM_FAULT_OP_WRITE; fault_type = MM_FAULT_TYPE_ACCESS_FAULT; break; case EP_STORE_ADDRESS_MISALIGNED: fault_op = MM_FAULT_OP_WRITE; fault_type = MM_FAULT_TYPE_BUS_ERROR; break; case EP_INSTRUCTION_PAGE_FAULT: fault_op = MM_FAULT_OP_EXECUTE; fault_type = MM_FAULT_TYPE_PAGE_FAULT; break; case EP_INSTRUCTION_ACCESS_FAULT: fault_op = MM_FAULT_OP_EXECUTE; fault_type = MM_FAULT_TYPE_ACCESS_FAULT; break; case EP_INSTRUCTION_ADDRESS_MISALIGNED: fault_op = MM_FAULT_OP_EXECUTE; fault_type = MM_FAULT_TYPE_BUS_ERROR; break; default: fault_op = 0; } if (fault_op) { struct rt_mm_fault_msg msg = { .fault_op = fault_op, .fault_type = fault_type, .vaddr = (void *)stval, }; if (rt_mm_fault_try_fix(&msg)) { return; } } LOG_E("[FATAL ERROR] Exception %ld:%s\n", id, get_exception_msg(id)); LOG_E("scause:0x%p,stval:0x%p,sepc:0x%p\n", scause, stval, sepc); dump_regs(sp); rt_hw_backtrace((uint32_t *)sp->s0_fp, sepc); LOG_E("User Fault, killing thread: %s", rt_thread_self()->name); EXIT_TRAP; sys_exit(-1); } #endif #ifdef ENABLE_VECTOR static void vector_enable(struct rt_hw_stack_frame *sp) { sp->sstatus |= SSTATUS_VS_INITIAL; } /** * detect V/D support, and do not distinguish V/D instruction */ static int illegal_inst_recoverable(rt_ubase_t stval, struct rt_hw_stack_frame *sp) { // first 7 bits is opcode int opcode = stval & 0x7f; int csr = (stval & 0xFFF00000) >> 20; // ref riscv-v-spec-1.0, [Vector Instruction Formats] int width = ((stval & 0x7000) >> 12) - 1; int flag = 0; switch (opcode) { case 0x57: // V case 0x27: // scalar FLOAT case 0x07: case 0x73: // CSR flag = 1; break; } if (flag) { vector_enable(sp); } return flag; } #endif static void handle_nested_trap_panic( rt_size_t cause, rt_size_t tval, rt_size_t epc, struct rt_hw_stack_frame *eframe) { LOG_E("\n-------- [SEVER ERROR] --------"); LOG_E("Nested trap detected"); LOG_E("scause:0x%p,stval:0x%p,sepc:0x%p\n", cause, tval, epc); dump_regs(eframe); rt_hw_cpu_shutdown(); } #define IN_USER_SPACE (stval >= USER_VADDR_START && stval < USER_VADDR_TOP) #define PAGE_FAULT (id == EP_LOAD_PAGE_FAULT || id == EP_STORE_PAGE_FAULT) /* Trap entry */ void handle_trap(rt_size_t scause, rt_size_t stval, rt_size_t sepc, struct rt_hw_stack_frame *sp) { ENTER_TRAP; rt_size_t id = __MASKVALUE(scause, __MASK(63UL)); const char *msg; /* supervisor external interrupt */ if (scause == (uint64_t)(0x8000000000000005)) { rt_interrupt_enter(); tick_isr(); rt_interrupt_leave(); } else if (scause == (uint64_t)(0x8000000000000009)) { rt_interrupt_enter(); int plic_irq = plic_claim(); plic_complete(plic_irq); irq_desc[plic_irq].handler(plic_irq, irq_desc[plic_irq].param); rt_interrupt_leave(); } else { // trap cannot nested when handling another trap / interrupt CHECK_NESTED_PANIC(scause, stval, sepc, sp); rt_size_t id = __MASKVALUE(scause, __MASK(63UL)); const char *msg; if (scause >> 63) { if (id < sizeof(Interrupt_Name) / sizeof(const char *)) { msg = Interrupt_Name[id]; } else { msg = "Unknown Interrupt"; } rt_kprintf("Unhandled Interrupt %ld:%s\n", id, msg); } else { #ifdef ENABLE_VECTOR if (scause == 0x2) { if (!(sp->sstatus & SSTATUS_VS) && illegal_inst_recoverable(stval, sp)) goto _exit; } #endif /* ENABLE_VECTOR */ #ifdef RT_USING_SMART if (!(sp->sstatus & 0x100) || (PAGE_FAULT && IN_USER_SPACE)) { handle_user(scause, stval, sepc, sp); // if handle_user() return here, jump to u mode then goto _exit; } #endif // handle kernel exception: rt_kprintf("Unhandled Exception %ld:%s\n", id, get_exception_msg(id)); } rt_kprintf("scause:0x%p,stval:0x%p,sepc:0x%p\n", scause, stval, sepc); dump_regs(sp); rt_kprintf("--------------Thread list--------------\n"); rt_kprintf("current thread: %s\n", rt_thread_self()->name); extern struct rt_thread *rt_current_thread; rt_kprintf("--------------Backtrace--------------\n"); rt_hw_backtrace((uint32_t *)sp->s0_fp, sepc); while (1) ; } _exit: EXIT_TRAP; return ; }