/* * mips.c - core analysis suite * * Copyright (C) 2015 Rabin Vincent * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #ifdef MIPS #include #include "defs.h" /* From arch/mips/asm/include/pgtable{,-32}.h */ typedef ulong pgd_t; typedef ulong pte_t; #define PTE_ORDER 0 #define PGD_T_LOG2 (__builtin_ffs(sizeof(pgd_t)) - 1) #define PTE_T_LOG2 (__builtin_ffs(sizeof(pte_t)) - 1) #define __PGD_ORDER (32 - 3 * (int)PAGESHIFT() + PGD_T_LOG2 + PTE_T_LOG2) #define PGD_ORDER (__PGD_ORDER >= 0 ? __PGD_ORDER : 0) #define PGD_SIZE (PAGESIZE() << PGD_ORDER) #define PGDIR_SHIFT (2 * PAGESHIFT() + PTE_ORDER - PTE_T_LOG2) #define PGDIR_SIZE (1UL << PGDIR_SHIFT) #define PGDIR_MASK (~(PGDIR_SIZE-1)) #define USER_PTRS_PER_PGD (0x80000000UL/PGDIR_SIZE) #define PTRS_PER_PGD (USER_PTRS_PER_PGD * 2) #define PTRS_PER_PTE ((PAGESIZE() << PTE_ORDER) / sizeof(pte_t)) #define pgd_index(address) (((address) >> PGDIR_SHIFT) & (PTRS_PER_PGD-1)) #define pte_offset(address) \ (((address) >> PAGESHIFT()) & (PTRS_PER_PTE - 1)) #define MIPS_CPU_RIXI 0x00800000llu #define MIPS32_EF_R0 6 #define MIPS32_EF_R29 35 #define MIPS32_EF_R31 37 #define MIPS32_EF_LO 38 #define MIPS32_EF_HI 39 #define MIPS32_EF_CP0_EPC 40 #define MIPS32_EF_CP0_BADVADDR 41 #define MIPS32_EF_CP0_STATUS 42 #define MIPS32_EF_CP0_CAUSE 43 static struct machine_specific mips_machine_specific = { 0 }; /* * Holds registers during the crash. */ static struct mips_regset *panic_task_regs; static void mips_display_machine_stats(void) { fprintf(fp, " HZ: %d\n", machdep->hz); fprintf(fp, " PAGE SIZE: %d\n", PAGESIZE()); fprintf(fp, "\n"); #define PRINT_PAGE_FLAG(flag) \ if (flag) \ fprintf(fp, " %14s: %08lx\n", #flag, flag) PRINT_PAGE_FLAG(_PAGE_PRESENT); PRINT_PAGE_FLAG(_PAGE_READ); PRINT_PAGE_FLAG(_PAGE_WRITE); PRINT_PAGE_FLAG(_PAGE_ACCESSED); PRINT_PAGE_FLAG(_PAGE_MODIFIED); PRINT_PAGE_FLAG(_PAGE_GLOBAL); PRINT_PAGE_FLAG(_PAGE_VALID); PRINT_PAGE_FLAG(_PAGE_NO_READ); PRINT_PAGE_FLAG(_PAGE_NO_EXEC); PRINT_PAGE_FLAG(_PAGE_DIRTY); } static void mips_cmd_mach(void) { int c; while ((c = getopt(argcnt, args, "")) != EOF) { switch(c) { default: argerrs++; break; } } if (argerrs) cmd_usage(pc->curcmd, SYNOPSIS); mips_display_machine_stats(); } #define PGDIR_OFFSET(X) (((ulong)(X)) & (PGD_SIZE - 1)) static void mips_init_page_flags(void) { ulong shift = 0; _PAGE_PRESENT = 1UL << shift++; if (THIS_KERNEL_VERSION >= LINUX(4,1,0)) { _PAGE_WRITE = 1UL << shift++; _PAGE_ACCESSED = 1UL << shift++; _PAGE_MODIFIED = 1UL << shift++; _PAGE_NO_EXEC = 1UL << shift++; _PAGE_READ = _PAGE_NO_READ = 1UL << shift++; } else { ulonglong cpu_options; int rixi; ulong addr; addr = symbol_value("cpu_data") + MEMBER_OFFSET("cpuinfo_mips", "options"); readmem(addr, KVADDR, &cpu_options, sizeof(cpu_options), "cpu_data[0].options", FAULT_ON_ERROR); rixi = cpu_options & MIPS_CPU_RIXI; if (!rixi) _PAGE_READ = 1UL << shift++; _PAGE_WRITE = 1UL << shift++; _PAGE_ACCESSED = 1UL << shift++; _PAGE_MODIFIED = 1UL << shift++; if (rixi) { _PAGE_NO_EXEC = 1UL << shift++; _PAGE_NO_READ = 1UL << shift++; } } _PAGE_GLOBAL = 1UL << shift++; _PAGE_VALID = 1UL << shift++; _PAGE_DIRTY = 1UL << shift++; _PFN_SHIFT = PAGESHIFT() - 12 + shift + 3; } static int mips_translate_pte(ulong pte, void *physaddr, ulonglong pte64) { char ptebuf[BUFSIZE]; char physbuf[BUFSIZE]; char buf[BUFSIZE]; int present; ulong paddr; int len1, len2, others; present = pte & _PAGE_PRESENT; paddr = (pte >> _PFN_SHIFT) << PAGESHIFT(); if (physaddr) { *(ulong *)physaddr = PAGEBASE(pte); return !!present; } sprintf(ptebuf, "%lx", pte); len1 = MAX(strlen(ptebuf), strlen("PTE")); fprintf(fp, "%s ", mkstring(buf, len1, CENTER | LJUST, "PTE")); if (!present) return !!present; sprintf(physbuf, "%lx", paddr); len2 = MAX(strlen(physbuf), strlen("PHYSICAL")); fprintf(fp, "%s ", mkstring(buf, len2, CENTER | LJUST, "PHYSICAL")); fprintf(fp, "FLAGS\n"); fprintf(fp, "%s %s ", mkstring(ptebuf, len1, CENTER | RJUST, NULL), mkstring(physbuf, len2, CENTER | RJUST, NULL)); fprintf(fp, "("); others = 0; #define CHECK_PAGE_FLAG(flag) \ if ((_PAGE_##flag) && (pte & _PAGE_##flag)) \ fprintf(fp, "%s" #flag, others++ ? "|" : "") if (pte) { CHECK_PAGE_FLAG(PRESENT); CHECK_PAGE_FLAG(READ); CHECK_PAGE_FLAG(WRITE); CHECK_PAGE_FLAG(ACCESSED); CHECK_PAGE_FLAG(MODIFIED); CHECK_PAGE_FLAG(GLOBAL); CHECK_PAGE_FLAG(VALID); CHECK_PAGE_FLAG(NO_READ); CHECK_PAGE_FLAG(NO_EXEC); CHECK_PAGE_FLAG(DIRTY); } else { fprintf(fp, "no mapping"); } fprintf(fp, ")\n"); return !!present; } static int mips_pgd_vtop(ulong *pgd, ulong vaddr, physaddr_t *paddr, int verbose) { ulong invalid_pte_table = symbol_value("invalid_pte_table"); ulong *page_dir; ulong pgd_pte, page_table; ulong pte; ulong pbase; if (verbose) { const char *segment; if (vaddr < 0x80000000lu) segment = "useg"; else if (vaddr < 0xa0000000lu) segment = "kseg0"; else if (vaddr < 0xc0000000lu) segment = "kseg1"; else if (vaddr < 0xe0000000lu) segment = "ksseg"; else segment = "kseg3"; fprintf(fp, "SEGMENT: %s\n", segment); } if (vaddr >= 0x80000000lu && vaddr < 0xc0000000lu) { *paddr = VTOP(vaddr); return TRUE; } if (verbose) fprintf(fp, "PAGE DIRECTORY: %lx\n", (ulong)pgd); page_dir = pgd + pgd_index(vaddr); FILL_PGD(PAGEBASE(pgd), KVADDR, PGD_SIZE); pgd_pte = ULONG(machdep->pgd + PGDIR_OFFSET(page_dir)); if (verbose) fprintf(fp, " PGD: %08lx => %lx\n", (ulong)page_dir, pgd_pte); if (pgd_pte == invalid_pte_table) { fprintf(fp, "invalid\n"); return FALSE; } page_table = VTOP(pgd_pte) + sizeof(pte_t) * pte_offset(vaddr); FILL_PTBL(PAGEBASE(page_table), PHYSADDR, PAGESIZE()); pte = ULONG(machdep->ptbl + PAGEOFFSET(page_table)); if (verbose) fprintf(fp, " PTE: %08lx => %08lx\n", page_table, pte); if (!(pte & _PAGE_PRESENT)) { if (verbose) { fprintf(fp, "\n"); mips_translate_pte((ulong)pte, 0, pte); } return FALSE; } pbase = (pte >> _PFN_SHIFT) << PAGESHIFT(); *paddr = pbase + PAGEOFFSET(vaddr); if (verbose) { fprintf(fp, " PAGE: %08lx\n\n", pbase); mips_translate_pte(pte, 0, 0); } return TRUE; } static int mips_uvtop(struct task_context *tc, ulong vaddr, physaddr_t *paddr, int verbose) { ulong *pgd; if (!tc) error(FATAL, "current context invalid\n"); if (is_kernel_thread(tc->task) && IS_KVADDR(vaddr)) { ulong active_mm; readmem(tc->task + OFFSET(task_struct_active_mm), KVADDR, &active_mm, sizeof(void *), "task active_mm contents", FAULT_ON_ERROR); if (!active_mm) error(FATAL, "no active_mm for this kernel thread\n"); readmem(active_mm + OFFSET(mm_struct_pgd), KVADDR, &pgd, sizeof(long), "mm_struct pgd", FAULT_ON_ERROR); } else { ulong mm; mm = task_mm(tc->task, TRUE); if (mm) pgd = ULONG_PTR(tt->mm_struct + OFFSET(mm_struct_pgd)); else readmem(tc->mm_struct + OFFSET(mm_struct_pgd), KVADDR, &pgd, sizeof(long), "mm_struct pgd", FAULT_ON_ERROR); } return mips_pgd_vtop(pgd, vaddr, paddr, verbose); } static int mips_kvtop(struct task_context *tc, ulong kvaddr, physaddr_t *paddr, int verbose) { if (!IS_KVADDR(kvaddr)) return FALSE; if (!verbose && !IS_VMALLOC_ADDR(kvaddr)) { *paddr = VTOP(kvaddr); return TRUE; } return mips_pgd_vtop((ulong *)vt->kernel_pgd[0], kvaddr, paddr, verbose); } static void mips_dump_exception_stack(struct bt_info *bt, char *pt_regs) { struct mips_pt_regs_main *mains; struct mips_pt_regs_cp0 *cp0; int i; char buf[BUFSIZE]; mains = (struct mips_pt_regs_main *) (pt_regs + OFFSET(pt_regs_regs)); cp0 = (struct mips_pt_regs_cp0 *) \ (pt_regs + OFFSET(pt_regs_cp0_badvaddr)); for (i = 0; i < 32; i += 4) { fprintf(fp, " $%2d : %08lx %08lx %08lx %08lx\n", i, mains->regs[i], mains->regs[i+1], mains->regs[i+2], mains->regs[i+3]); } fprintf(fp, " Hi : %08lx\n", mains->hi); fprintf(fp, " Lo : %08lx\n", mains->lo); value_to_symstr(cp0->cp0_epc, buf, 16); fprintf(fp, " epc : %08lx %s\n", cp0->cp0_epc, buf); value_to_symstr(mains->regs[31], buf, 16); fprintf(fp, " ra : %08lx %s\n", mains->regs[31], buf); fprintf(fp, " Status: %08lx\n", mains->cp0_status); fprintf(fp, " Cause : %08lx\n", cp0->cp0_cause); fprintf(fp, " BadVA : %08lx\n", cp0->cp0_badvaddr); } struct mips_unwind_frame { ulong sp; ulong pc; ulong ra; }; static void mips_display_full_frame(struct bt_info *bt, struct mips_unwind_frame *current, struct mips_unwind_frame *previous) { ulong words, addr; ulong *up; char buf[BUFSIZE]; int i, u_idx; if (!INSTACK(previous->sp, bt) || !INSTACK(current->sp, bt)) return; words = (previous->sp - current->sp) / sizeof(ulong); if (words == 0) { fprintf(fp, " (no frame)\n"); return; } addr = current->sp; u_idx = (current->sp - bt->stackbase) / sizeof(ulong); for (i = 0; i < words; i++, u_idx++) { if ((i % 4) == 0) fprintf(fp, "%s %lx: ", i ? "\n" : "", addr); up = (ulong *)(&bt->stackbuf[u_idx * sizeof(ulong)]); fprintf(fp, "%s ", format_stack_entry(bt, buf, *up, 0)); addr += sizeof(ulong); } fprintf(fp, "\n"); } static int mips_is_exception_entry(struct syment *sym) { return STREQ(sym->name, "ret_from_exception") || STREQ(sym->name, "ret_from_irq") || STREQ(sym->name, "work_resched") || STREQ(sym->name, "handle_sys"); } static void mips_dump_backtrace_entry(struct bt_info *bt, struct syment *sym, struct mips_unwind_frame *current, struct mips_unwind_frame *previous, int level) { const char *name = sym ? sym->name : "(invalid)"; struct load_module *lm; char *name_plus_offset; char buf[BUFSIZE]; name_plus_offset = NULL; if (bt->flags & BT_SYMBOL_OFFSET) { struct syment *symp; ulong symbol_offset; symp = value_search(current->pc, &symbol_offset); if (symp && symbol_offset) name_plus_offset = value_to_symstr(current->pc, buf, bt->radix); } fprintf(fp, "%s#%d [%8lx] %s at %lx", level < 10 ? " " : "", level, current->sp, name_plus_offset ? name_plus_offset : name, current->pc); if (module_symbol(current->pc, NULL, &lm, NULL, 0)) fprintf(fp, " [%s]", lm->mod_name); fprintf(fp, "\n"); if (bt->flags & BT_LINE_NUMBERS) { char buf[BUFSIZE]; get_line_number(current->pc, buf, FALSE); if (strlen(buf)) fprintf(fp, " %s\n", buf); } if (sym && mips_is_exception_entry(sym)) { char pt_regs[SIZE(pt_regs)]; GET_STACK_DATA(current->sp, &pt_regs, SIZE(pt_regs)); mips_dump_exception_stack(bt, pt_regs); } if (bt->flags & BT_FULL) { fprintf(fp, " " "[PC: %08lx RA: %08lx SP: %08lx SIZE: %ld]\n", current->pc, current->ra, current->sp, previous->sp - current->sp); mips_display_full_frame(bt, current, previous); } } static void mips_analyze_function(ulong start, ulong offset, struct mips_unwind_frame *current, struct mips_unwind_frame *previous) { ulong rapos = 0; ulong spadjust = 0; ulong *funcbuf, *ip; ulong i; if (CRASHDEBUG(8)) fprintf(fp, "%s: start %#lx offset %#lx\n", __func__, start, offset); if (!offset) { previous->sp = current->sp; return; } ip = funcbuf = (ulong *)GETBUF(offset); if (!readmem(start, KVADDR, funcbuf, offset, "mips_analyze_function", RETURN_ON_ERROR)) { FREEBUF(funcbuf); error(FATAL, "Cannot read function at %8x", start); return; } for (i = 0; i < offset; i += 4) { ulong insn = *ip; ulong high = (insn >> 16) & 0xffff; ulong low = insn & 0xffff; if (CRASHDEBUG(8)) fprintf(fp, "insn @ %#lx = %#lx\n", start + i, insn); if (high == 0x27bd) { /* ADDIU sp, sp, imm */ if (!(low & 0x8000)) break; spadjust += 0x10000 - low; if (CRASHDEBUG(8)) fprintf(fp, "spadjust = %lu\n", spadjust); } else if (high == 0xafbf) { /* SW RA, imm(SP) */ rapos = current->sp + low; if (CRASHDEBUG(8)) fprintf(fp, "rapos %lx\n", rapos); break; } ip++; } FREEBUF(funcbuf); previous->sp = current->sp + spadjust; if (rapos && !readmem(rapos, KVADDR, ¤t->ra, sizeof(current->ra), "RA from stack", RETURN_ON_ERROR)) { error(FATAL, "Cannot read RA from stack %lx", rapos); return; } } static void mips_back_trace_cmd(struct bt_info *bt) { struct mips_unwind_frame current, previous; int level = 0; int invalid_ok = 1; if (bt->flags & BT_REGS_NOT_FOUND) return; previous.sp = previous.pc = previous.ra = 0; current.pc = bt->instptr; current.sp = bt->stkptr; current.ra = 0; if (bt->machdep) { struct mips_regset *regs = bt->machdep; previous.pc = current.ra = regs->regs[MIPS32_EF_R31]; } while (INSTACK(current.sp, bt)) { struct syment *symbol = NULL; ulong offset; if (CRASHDEBUG(8)) fprintf(fp, "level %d pc %#lx ra %#lx sp %lx\n", level, current.pc, current.ra, current.sp); if (!IS_KVADDR(current.pc) && !invalid_ok) return; symbol = value_search(current.pc, &offset); if (!symbol && !invalid_ok) { error(FATAL, "PC is unknown symbol (%lx)", current.pc); return; } invalid_ok = 0; /* * If we get an address which points to the start of a * function, then it could one of the following: * * - we are dealing with a noreturn function. The last call * from a noreturn function has an an ra which points to the * start of the function after it. This is common in the * oops callchain because of die() which is annotated as * noreturn. * * - we have taken an exception at the start of this function. * In this case we already have the RA in current.ra. * * - we are in one of these routines which appear with zero * offset in manually-constructed stack frames: * * * ret_from_exception * * ret_from_irq * * ret_from_fork * * ret_from_kernel_thread */ if (!current.ra && !offset && symbol && !STRNEQ(symbol->name, "ret_from")) { if (CRASHDEBUG(8)) fprintf(fp, "zero offset at %s, try previous symbol\n", symbol->name); symbol = value_search(current.pc - 4, &offset); if (!symbol) { error(FATAL, "PC is unknown symbol (%lx)", current.pc); return; } } if (symbol && mips_is_exception_entry(symbol)) { struct mips_pt_regs_main *mains; struct mips_pt_regs_cp0 *cp0; char pt_regs[SIZE(pt_regs)]; mains = (struct mips_pt_regs_main *) \ (pt_regs + OFFSET(pt_regs_regs)); cp0 = (struct mips_pt_regs_cp0 *) \ (pt_regs + OFFSET(pt_regs_cp0_badvaddr)); GET_STACK_DATA(current.sp, pt_regs, sizeof(pt_regs)); previous.ra = mains->regs[31]; previous.sp = mains->regs[29]; current.ra = cp0->cp0_epc; if (CRASHDEBUG(8)) fprintf(fp, "exception pc %#lx ra %#lx sp %lx\n", previous.pc, previous.ra, previous.sp); /* The PC causing the exception may have been invalid */ invalid_ok = 1; } else if (symbol) { mips_analyze_function(symbol->value, offset, ¤t, &previous); } else { /* * The current PC is invalid. Assume that the code * jumped through a invalid pointer and that the SP has * not been adjusted. */ previous.sp = current.sp; } mips_dump_backtrace_entry(bt, symbol, ¤t, &previous, level++); current.pc = current.ra; current.sp = previous.sp; current.ra = previous.ra; if (CRASHDEBUG(8)) fprintf(fp, "next %d pc %#lx ra %#lx sp %lx\n", level, current.pc, current.ra, current.sp); previous.sp = previous.pc = previous.ra = 0; } } static int mips_dumpfile_stack_frame(struct bt_info *bt, ulong *nip, ulong *ksp) { const struct machine_specific *ms = machdep->machspec; struct mips_regset *regs; ulong epc, r29; if (!ms->crash_task_regs) { bt->flags |= BT_REGS_NOT_FOUND; return FALSE; } regs = &ms->crash_task_regs[bt->tc->processor]; epc = regs->regs[MIPS32_EF_CP0_EPC]; r29 = regs->regs[MIPS32_EF_R29]; if (!epc && !r29) { bt->flags |= BT_REGS_NOT_FOUND; return FALSE; } if (nip) *nip = epc; if (ksp) *ksp = r29; bt->machdep = regs; return TRUE; } static int mips_get_frame(struct bt_info *bt, ulong *pcp, ulong *spp) { if (!bt->tc || !(tt->flags & THREAD_INFO)) return FALSE; if (!readmem(bt->task + OFFSET(task_struct_thread_reg31), KVADDR, pcp, sizeof(*pcp), "thread_struct.regs31", RETURN_ON_ERROR)) { return FALSE; } if (!readmem(bt->task + OFFSET(task_struct_thread_reg29), KVADDR, spp, sizeof(*spp), "thread_struct.regs29", RETURN_ON_ERROR)) { return FALSE; } return TRUE; } static void mips_stackframe_init(void) { long task_struct_thread = MEMBER_OFFSET("task_struct", "thread"); long thread_reg29 = MEMBER_OFFSET("thread_struct", "reg29"); long thread_reg31 = MEMBER_OFFSET("thread_struct", "reg31"); if ((task_struct_thread == INVALID_OFFSET) || (thread_reg29 == INVALID_OFFSET) || (thread_reg31 == INVALID_OFFSET)) { error(FATAL, "cannot determine thread_struct offsets\n"); return; } ASSIGN_OFFSET(task_struct_thread_reg29) = task_struct_thread + thread_reg29; ASSIGN_OFFSET(task_struct_thread_reg31) = task_struct_thread + thread_reg31; STRUCT_SIZE_INIT(pt_regs, "pt_regs"); MEMBER_OFFSET_INIT(pt_regs_regs, "pt_regs", "regs"); MEMBER_OFFSET_INIT(pt_regs_cp0_badvaddr, "pt_regs", "cp0_badvaddr"); } static void mips_get_stack_frame(struct bt_info *bt, ulong *pcp, ulong *spp) { int ret; *pcp = 0; *spp = 0; bt->machdep = NULL; if (DUMPFILE() && is_task_active(bt->task)) ret = mips_dumpfile_stack_frame(bt, pcp, spp); else ret = mips_get_frame(bt, pcp, spp); if (!ret) error(WARNING, "cannot determine starting stack frame for task %lx\n", bt->task); } static int mips_eframe_search(struct bt_info *bt) { return error(FATAL, "%s: not implemented\n", __func__); } static ulong mips_get_task_pgd(ulong task) { return error(FATAL, "%s: not implemented\n", __func__); } static int mips_is_task_addr(ulong task) { if (tt->flags & THREAD_INFO) return IS_KVADDR(task); return (IS_KVADDR(task) && ALIGNED_STACK_OFFSET(task) == 0); } static ulong mips_processor_speed(void) { return 0; } static int mips_get_smp_cpus(void) { return (get_cpus_online() > 0) ? get_cpus_online() : kt->cpus; } static ulong mips_vmalloc_start(void) { return first_vmalloc_address(); } /* * Retrieve task registers for the time of the crash. */ static int mips_get_crash_notes(void) { struct machine_specific *ms = machdep->machspec; ulong crash_notes; Elf32_Nhdr *note; ulong offset; char *buf, *p; ulong *notes_ptrs; ulong i; if (!symbol_exists("crash_notes")) return FALSE; crash_notes = symbol_value("crash_notes"); notes_ptrs = (ulong *)GETBUF(kt->cpus*sizeof(notes_ptrs[0])); /* * Read crash_notes for the first CPU. crash_notes are in standard ELF * note format. */ if (!readmem(crash_notes, KVADDR, ¬es_ptrs[kt->cpus-1], sizeof(notes_ptrs[kt->cpus-1]), "crash_notes", RETURN_ON_ERROR)) { error(WARNING, "cannot read crash_notes\n"); FREEBUF(notes_ptrs); return FALSE; } if (symbol_exists("__per_cpu_offset")) { /* Add __per_cpu_offset for each cpu to form the pointer to the notes */ for (i = 0; icpus; i++) notes_ptrs[i] = notes_ptrs[kt->cpus-1] + kt->__per_cpu_offset[i]; } buf = GETBUF(SIZE(note_buf)); if (!(panic_task_regs = calloc((size_t)kt->cpus, sizeof(*panic_task_regs)))) error(FATAL, "cannot calloc panic_task_regs space\n"); for (i=0;icpus;i++) { if (!readmem(notes_ptrs[i], KVADDR, buf, SIZE(note_buf), "note_buf_t", RETURN_ON_ERROR)) { error(WARNING, "failed to read note_buf_t\n"); goto fail; } /* * Do some sanity checks for this note before reading registers from it. */ note = (Elf32_Nhdr *)buf; p = buf + sizeof(Elf32_Nhdr); /* * dumpfiles created with qemu won't have crash_notes, but there will * be elf notes; dumpfiles created by kdump do not create notes for * offline cpus. */ if (note->n_namesz == 0 && (DISKDUMP_DUMPFILE() || KDUMP_DUMPFILE())) { if (DISKDUMP_DUMPFILE()) note = diskdump_get_prstatus_percpu(i); else if (KDUMP_DUMPFILE()) note = netdump_get_prstatus_percpu(i); if (note) { /* * SIZE(note_buf) accounts for a "final note", which is a * trailing empty elf note header. */ long notesz = SIZE(note_buf) - sizeof(Elf32_Nhdr); if (sizeof(Elf32_Nhdr) + roundup(note->n_namesz, 4) + note->n_descsz == notesz) BCOPY((char *)note, buf, notesz); } else { error(WARNING, "cannot find NT_PRSTATUS note for cpu: %d\n", i); continue; } } if (note->n_type != NT_PRSTATUS) { error(WARNING, "invalid note (n_type != NT_PRSTATUS)\n"); goto fail; } if (p[0] != 'C' || p[1] != 'O' || p[2] != 'R' || p[3] != 'E') { error(WARNING, "invalid note (name != \"CORE\"\n"); goto fail; } /* * Find correct location of note data. This contains elf_prstatus * structure which has registers etc. for the crashed task. */ offset = sizeof(Elf32_Nhdr); offset = roundup(offset + note->n_namesz, 4); p = buf + offset; /* start of elf_prstatus */ BCOPY(p + OFFSET(elf_prstatus_pr_reg), &panic_task_regs[i], sizeof(panic_task_regs[i])); } /* * And finally we have the registers for the crashed task. This is * used later on when dumping backtrace. */ ms->crash_task_regs = panic_task_regs; FREEBUF(buf); FREEBUF(notes_ptrs); return TRUE; fail: FREEBUF(buf); FREEBUF(notes_ptrs); free(panic_task_regs); return FALSE; } static int mips_get_elf_notes(void) { struct machine_specific *ms = machdep->machspec; int i; if (!DISKDUMP_DUMPFILE() && !KDUMP_DUMPFILE()) return FALSE; panic_task_regs = calloc(kt->cpus, sizeof(*panic_task_regs)); if (!panic_task_regs) error(FATAL, "cannot calloc panic_task_regs space\n"); for (i = 0; i < kt->cpus; i++) { Elf32_Nhdr *note = NULL; size_t len; if (DISKDUMP_DUMPFILE()) note = diskdump_get_prstatus_percpu(i); else if (KDUMP_DUMPFILE()) note = netdump_get_prstatus_percpu(i); if (!note) { error(WARNING, "cannot find NT_PRSTATUS note for cpu: %d\n", i); continue; } len = sizeof(Elf32_Nhdr); len = roundup(len + note->n_namesz, 4); BCOPY((char *)note + len + OFFSET(elf_prstatus_pr_reg), &panic_task_regs[i], sizeof(panic_task_regs[i])); } ms->crash_task_regs = panic_task_regs; return TRUE; } static int mips_init_active_task_regs(void) { int retval; retval = mips_get_crash_notes(); if (retval == TRUE) return retval; return mips_get_elf_notes(); } static int mips_verify_symbol(const char *name, ulong value, char type) { if (STREQ(name, "_text")) machdep->flags |= KSYMS_START; return (name && strlen(name) && (machdep->flags & KSYMS_START) && !STRNEQ(name, "__func__.") && !STRNEQ(name, "__crc_")); } void mips_dump_machdep_table(ulong arg) { int others = 0; fprintf(fp, " flags: %lx (", machdep->flags); if (machdep->flags & KSYMS_START) fprintf(fp, "%sKSYMS_START", others++ ? "|" : ""); fprintf(fp, ")\n"); fprintf(fp, " kvbase: %lx\n", machdep->kvbase); fprintf(fp, " identity_map_base: %lx\n", machdep->identity_map_base); fprintf(fp, " pagesize: %d\n", machdep->pagesize); fprintf(fp, " pageshift: %d\n", machdep->pageshift); fprintf(fp, " pagemask: %llx\n", machdep->pagemask); fprintf(fp, " pageoffset: %lx\n", machdep->pageoffset); fprintf(fp, " pgdir_shift: %d\n", PGDIR_SHIFT); fprintf(fp, " ptrs_per_pgd: %lu\n", PTRS_PER_PGD); fprintf(fp, " ptrs_per_pte: %d\n", PTRS_PER_PTE); fprintf(fp, " stacksize: %ld\n", machdep->stacksize); fprintf(fp, " hz: %d\n", machdep->hz); fprintf(fp, " memsize: %lld (0x%llx)\n", machdep->memsize, machdep->memsize); fprintf(fp, " bits: %d\n", machdep->bits); fprintf(fp, " nr_irqs: %d\n", machdep->nr_irqs); fprintf(fp, " eframe_search: mips_eframe_search()\n"); fprintf(fp, " back_trace: mips_back_trace_cmd()\n"); fprintf(fp, " processor_speed: mips_processor_speed()\n"); fprintf(fp, " uvtop: mips_uvtop()\n"); fprintf(fp, " kvtop: mips_kvtop()\n"); fprintf(fp, " get_task_pgd: mips_get_task_pgd()\n"); fprintf(fp, " dump_irq: generic_dump_irq()\n"); fprintf(fp, " show_interrupts: generic_show_interrupts()\n"); fprintf(fp, " get_irq_affinity: generic_get_irq_affinity()\n"); fprintf(fp, " get_stack_frame: mips_get_stack_frame()\n"); fprintf(fp, " get_stackbase: generic_get_stackbase()\n"); fprintf(fp, " get_stacktop: generic_get_stacktop()\n"); fprintf(fp, " translate_pte: mips_translate_pte()\n"); fprintf(fp, " memory_size: generic_memory_size()\n"); fprintf(fp, " vmalloc_start: mips_vmalloc_start()\n"); fprintf(fp, " is_task_addr: mips_is_task_addr()\n"); fprintf(fp, " verify_symbol: mips_verify_symbol()\n"); fprintf(fp, " dis_filter: generic_dis_filter()\n"); fprintf(fp, " cmd_mach: mips_cmd_mach()\n"); fprintf(fp, " get_smp_cpus: mips_get_smp_cpus()\n"); fprintf(fp, " is_kvaddr: generic_is_kvaddr()\n"); fprintf(fp, " is_uvaddr: generic_is_uvaddr()\n"); fprintf(fp, " verify_paddr: generic_verify_paddr()\n"); fprintf(fp, " init_kernel_pgd: NULL\n"); fprintf(fp, " value_to_symbol: generic_machdep_value_to_symbol()\n"); fprintf(fp, " line_number_hooks: NULL\n"); fprintf(fp, " last_pgd_read: %lx\n", machdep->last_pgd_read); fprintf(fp, " last_pmd_read: %lx\n", machdep->last_pmd_read); fprintf(fp, " last_ptbl_read: %lx\n", machdep->last_ptbl_read); fprintf(fp, " pgd: %lx\n", (ulong)machdep->pgd); fprintf(fp, " pmd: %lx\n", (ulong)machdep->pmd); fprintf(fp, " ptbl: %lx\n", (ulong)machdep->ptbl); fprintf(fp, " section_size_bits: %ld\n", machdep->section_size_bits); fprintf(fp, " max_physmem_bits: %ld\n", machdep->max_physmem_bits); fprintf(fp, " sections_per_root: %ld\n", machdep->sections_per_root); fprintf(fp, " machspec: %lx\n", (ulong)machdep->machspec); } static ulong mips_get_page_size(void) { struct syment *spd, *next = NULL; spd = symbol_search("swapper_pg_dir"); if (spd) next = next_symbol(NULL, spd); if (!spd || !next) return memory_page_size(); return next->value - spd->value; } void mips_init(int when) { #if defined(__i386__) || defined(__x86_64__) if (ACTIVE()) error(FATAL, "compiled for the MIPS architecture\n"); #endif switch (when) { case SETUP_ENV: machdep->process_elf_notes = process_elf32_notes; break; case PRE_SYMTAB: machdep->verify_symbol = mips_verify_symbol; machdep->machspec = &mips_machine_specific; if (pc->flags & KERNEL_DEBUG_QUERY) return; machdep->last_pgd_read = 0; machdep->last_pmd_read = 0; machdep->last_ptbl_read = 0; machdep->verify_paddr = generic_verify_paddr; machdep->ptrs_per_pgd = PTRS_PER_PGD; break; case PRE_GDB: machdep->pagesize = mips_get_page_size(); machdep->pageshift = ffs(machdep->pagesize) - 1; machdep->pageoffset = machdep->pagesize - 1; machdep->pagemask = ~((ulonglong)machdep->pageoffset); if (machdep->pagesize >= 16384) machdep->stacksize = machdep->pagesize; else machdep->stacksize = machdep->pagesize * 2; if ((machdep->pgd = malloc(PGD_SIZE)) == NULL) error(FATAL, "cannot malloc pgd space."); if ((machdep->ptbl = malloc(PAGESIZE())) == NULL) error(FATAL, "cannot malloc ptbl space."); machdep->kvbase = 0x80000000; machdep->identity_map_base = machdep->kvbase; machdep->is_kvaddr = generic_is_kvaddr; machdep->is_uvaddr = generic_is_uvaddr; machdep->uvtop = mips_uvtop; machdep->kvtop = mips_kvtop; machdep->vmalloc_start = mips_vmalloc_start; machdep->eframe_search = mips_eframe_search; machdep->back_trace = mips_back_trace_cmd; machdep->processor_speed = mips_processor_speed; machdep->get_task_pgd = mips_get_task_pgd; machdep->get_stack_frame = mips_get_stack_frame; machdep->get_stackbase = generic_get_stackbase; machdep->get_stacktop = generic_get_stacktop; machdep->translate_pte = mips_translate_pte; machdep->memory_size = generic_memory_size; machdep->is_task_addr = mips_is_task_addr; machdep->dis_filter = generic_dis_filter; machdep->cmd_mach = mips_cmd_mach; machdep->get_smp_cpus = mips_get_smp_cpus; machdep->value_to_symbol = generic_machdep_value_to_symbol; machdep->init_kernel_pgd = NULL; break; case POST_GDB: mips_init_page_flags(); machdep->dump_irq = generic_dump_irq; machdep->show_interrupts = generic_show_interrupts; machdep->get_irq_affinity = generic_get_irq_affinity; machdep->section_size_bits = _SECTION_SIZE_BITS; machdep->max_physmem_bits = _MAX_PHYSMEM_BITS; if (symbol_exists("irq_desc")) ARRAY_LENGTH_INIT(machdep->nr_irqs, irq_desc, "irq_desc", NULL, 0); else if (kernel_symbol_exists("nr_irqs")) get_symbol_data("nr_irqs", sizeof(unsigned int), &machdep->nr_irqs); mips_stackframe_init(); if (!machdep->hz) machdep->hz = 100; MEMBER_OFFSET_INIT(elf_prstatus_pr_reg, "elf_prstatus", "pr_reg"); STRUCT_SIZE_INIT(note_buf, "note_buf_t"); break; case POST_VM: /* * crash_notes contains machine specific information about the * crash. In particular, it contains CPU registers at the time * of the crash. We need this information to extract correct * backtraces from the panic task. */ if (!ACTIVE() && !mips_init_active_task_regs()) error(WARNING, "cannot retrieve registers for active task%s\n\n", kt->cpus > 1 ? "s" : ""); } } void mips_display_regs_from_elf_notes(int cpu, FILE *ofp) { const struct machine_specific *ms = machdep->machspec; struct mips_regset *regs; if (!ms->crash_task_regs) { error(INFO, "registers not collected for cpu %d\n", cpu); return; } regs = &ms->crash_task_regs[cpu]; if (!regs->regs[MIPS32_EF_R29] && !regs->regs[MIPS32_EF_CP0_EPC]) { error(INFO, "registers not collected for cpu %d\n", cpu); return; } fprintf(ofp, " R0: %08lx R1: %08lx R2: %08lx\n" " R3: %08lx R4: %08lx R5: %08lx\n" " R6: %08lx R7: %08lx R8: %08lx\n" " R9: %08lx R10: %08lx R11: %08lx\n" " R12: %08lx R13: %08lx R14: %08lx\n" " R15: %08lx R16: %08lx R17: %08lx\n" " R18: %08lx R19: %08lx R20: %08lx\n" " R21: %08lx R22: %08lx R23: %08lx\n" " R24: %08lx R25: %08lx R26: %08lx\n" " R27: %08lx R28: %08lx R29: %08lx\n" " R30: %08lx R31: %08lx\n" " LO: %08lx HI: %08lx\n" " EPC: %08lx BADVADDR: %08lx\n" " STATUS: %08lx CAUSE: %08lx\n", regs->regs[MIPS32_EF_R0], regs->regs[MIPS32_EF_R0 + 1], regs->regs[MIPS32_EF_R0 + 2], regs->regs[MIPS32_EF_R0 + 3], regs->regs[MIPS32_EF_R0 + 4], regs->regs[MIPS32_EF_R0 + 5], regs->regs[MIPS32_EF_R0 + 6], regs->regs[MIPS32_EF_R0 + 7], regs->regs[MIPS32_EF_R0 + 8], regs->regs[MIPS32_EF_R0 + 9], regs->regs[MIPS32_EF_R0 + 10], regs->regs[MIPS32_EF_R0 + 11], regs->regs[MIPS32_EF_R0 + 12], regs->regs[MIPS32_EF_R0 + 13], regs->regs[MIPS32_EF_R0 + 14], regs->regs[MIPS32_EF_R0 + 15], regs->regs[MIPS32_EF_R0 + 16], regs->regs[MIPS32_EF_R0 + 17], regs->regs[MIPS32_EF_R0 + 18], regs->regs[MIPS32_EF_R0 + 19], regs->regs[MIPS32_EF_R0 + 20], regs->regs[MIPS32_EF_R0 + 21], regs->regs[MIPS32_EF_R0 + 22], regs->regs[MIPS32_EF_R0 + 23], regs->regs[MIPS32_EF_R0 + 24], regs->regs[MIPS32_EF_R0 + 25], regs->regs[MIPS32_EF_R0 + 26], regs->regs[MIPS32_EF_R0 + 27], regs->regs[MIPS32_EF_R0 + 28], regs->regs[MIPS32_EF_R0 + 29], regs->regs[MIPS32_EF_R0 + 30], regs->regs[MIPS32_EF_R0 + 31], regs->regs[MIPS32_EF_LO], regs->regs[MIPS32_EF_HI], regs->regs[MIPS32_EF_CP0_EPC], regs->regs[MIPS32_EF_CP0_BADVADDR], regs->regs[MIPS32_EF_CP0_STATUS], regs->regs[MIPS32_EF_CP0_CAUSE]); } #else #include "defs.h" void mips_display_regs_from_elf_notes(int cpu, FILE *ofp) { return; } #endif /* !MIPS */