// SPDX-License-Identifier: GPL-2.0-only /* * entry_from_vm86.c - tests kernel entries from vm86 mode * Copyright (c) 2014-2015 Andrew Lutomirski * * This exercises a few paths that need to special-case vm86 mode. */ #define _GNU_SOURCE #include <assert.h> #include <stdlib.h> #include <sys/syscall.h> #include <sys/signal.h> #include <sys/ucontext.h> #include <unistd.h> #include <stdio.h> #include <string.h> #include <inttypes.h> #include <sys/mman.h> #include <err.h> #include <stddef.h> #include <stdbool.h> #include <errno.h> #include <sys/vm86.h> static unsigned long load_addr = 0x10000; static int nerrs = 0; static void sethandler(int sig, void (*handler)(int, siginfo_t *, void *), int flags) { struct sigaction sa; memset(&sa, 0, sizeof(sa)); sa.sa_sigaction = handler; sa.sa_flags = SA_SIGINFO | flags; sigemptyset(&sa.sa_mask); if (sigaction(sig, &sa, 0)) err(1, "sigaction"); } static void clearhandler(int sig) { struct sigaction sa; memset(&sa, 0, sizeof(sa)); sa.sa_handler = SIG_DFL; sigemptyset(&sa.sa_mask); if (sigaction(sig, &sa, 0)) err(1, "sigaction"); } static sig_atomic_t got_signal; static void sighandler(int sig, siginfo_t *info, void *ctx_void) { ucontext_t *ctx = (ucontext_t*)ctx_void; if (ctx->uc_mcontext.gregs[REG_EFL] & X86_EFLAGS_VM || (ctx->uc_mcontext.gregs[REG_CS] & 3) != 3) { printf("[FAIL]\tSignal frame should not reflect vm86 mode\n"); nerrs++; } const char *signame; if (sig == SIGSEGV) signame = "SIGSEGV"; else if (sig == SIGILL) signame = "SIGILL"; else signame = "unexpected signal"; printf("[INFO]\t%s: FLAGS = 0x%lx, CS = 0x%hx\n", signame, (unsigned long)ctx->uc_mcontext.gregs[REG_EFL], (unsigned short)ctx->uc_mcontext.gregs[REG_CS]); got_signal = 1; } asm ( ".pushsection .rodata\n\t" ".type vmcode_bound, @object\n\t" "vmcode:\n\t" "vmcode_bound:\n\t" ".code16\n\t" "bound %ax, (2048)\n\t" "int3\n\t" "vmcode_sysenter:\n\t" "sysenter\n\t" "vmcode_syscall:\n\t" "syscall\n\t" "vmcode_sti:\n\t" "sti\n\t" "vmcode_int3:\n\t" "int3\n\t" "vmcode_int80:\n\t" "int $0x80\n\t" "vmcode_popf_hlt:\n\t" "push %ax\n\t" "popf\n\t" "hlt\n\t" "vmcode_umip:\n\t" /* addressing via displacements */ "smsw (2052)\n\t" "sidt (2054)\n\t" "sgdt (2060)\n\t" /* addressing via registers */ "mov $2066, %bx\n\t" "smsw (%bx)\n\t" "mov $2068, %bx\n\t" "sidt (%bx)\n\t" "mov $2074, %bx\n\t" "sgdt (%bx)\n\t" /* register operands, only for smsw */ "smsw %ax\n\t" "mov %ax, (2080)\n\t" "int3\n\t" "vmcode_umip_str:\n\t" "str %eax\n\t" "vmcode_umip_sldt:\n\t" "sldt %eax\n\t" "int3\n\t" ".size vmcode, . - vmcode\n\t" "end_vmcode:\n\t" ".code32\n\t" ".popsection" ); extern unsigned char vmcode[], end_vmcode[]; extern unsigned char vmcode_bound[], vmcode_sysenter[], vmcode_syscall[], vmcode_sti[], vmcode_int3[], vmcode_int80[], vmcode_popf_hlt[], vmcode_umip[], vmcode_umip_str[], vmcode_umip_sldt[]; /* Returns false if the test was skipped. */ static bool do_test(struct vm86plus_struct *v86, unsigned long eip, unsigned int rettype, unsigned int retarg, const char *text) { long ret; printf("[RUN]\t%s from vm86 mode\n", text); v86->regs.eip = eip; ret = vm86(VM86_ENTER, v86); if (ret == -1 && (errno == ENOSYS || errno == EPERM)) { printf("[SKIP]\tvm86 %s\n", errno == ENOSYS ? "not supported" : "not allowed"); return false; } if (VM86_TYPE(ret) == VM86_INTx) { char trapname[32]; int trapno = VM86_ARG(ret); if (trapno == 13) strcpy(trapname, "GP"); else if (trapno == 5) strcpy(trapname, "BR"); else if (trapno == 14) strcpy(trapname, "PF"); else sprintf(trapname, "%d", trapno); printf("[INFO]\tExited vm86 mode due to #%s\n", trapname); } else if (VM86_TYPE(ret) == VM86_UNKNOWN) { printf("[INFO]\tExited vm86 mode due to unhandled GP fault\n"); } else if (VM86_TYPE(ret) == VM86_TRAP) { printf("[INFO]\tExited vm86 mode due to a trap (arg=%ld)\n", VM86_ARG(ret)); } else if (VM86_TYPE(ret) == VM86_SIGNAL) { printf("[INFO]\tExited vm86 mode due to a signal\n"); } else if (VM86_TYPE(ret) == VM86_STI) { printf("[INFO]\tExited vm86 mode due to STI\n"); } else { printf("[INFO]\tExited vm86 mode due to type %ld, arg %ld\n", VM86_TYPE(ret), VM86_ARG(ret)); } if (rettype == -1 || (VM86_TYPE(ret) == rettype && VM86_ARG(ret) == retarg)) { printf("[OK]\tReturned correctly\n"); } else { printf("[FAIL]\tIncorrect return reason (started at eip = 0x%lx, ended at eip = 0x%lx)\n", eip, v86->regs.eip); nerrs++; } return true; } void do_umip_tests(struct vm86plus_struct *vm86, unsigned char *test_mem) { struct table_desc { unsigned short limit; unsigned long base; } __attribute__((packed)); /* Initialize variables with arbitrary values */ struct table_desc gdt1 = { .base = 0x3c3c3c3c, .limit = 0x9999 }; struct table_desc gdt2 = { .base = 0x1a1a1a1a, .limit = 0xaeae }; struct table_desc idt1 = { .base = 0x7b7b7b7b, .limit = 0xf1f1 }; struct table_desc idt2 = { .base = 0x89898989, .limit = 0x1313 }; unsigned short msw1 = 0x1414, msw2 = 0x2525, msw3 = 3737; /* UMIP -- exit with INT3 unless kernel emulation did not trap #GP */ do_test(vm86, vmcode_umip - vmcode, VM86_TRAP, 3, "UMIP tests"); /* Results from displacement-only addressing */ msw1 = *(unsigned short *)(test_mem + 2052); memcpy(&idt1, test_mem + 2054, sizeof(idt1)); memcpy(&gdt1, test_mem + 2060, sizeof(gdt1)); /* Results from register-indirect addressing */ msw2 = *(unsigned short *)(test_mem + 2066); memcpy(&idt2, test_mem + 2068, sizeof(idt2)); memcpy(&gdt2, test_mem + 2074, sizeof(gdt2)); /* Results when using register operands */ msw3 = *(unsigned short *)(test_mem + 2080); printf("[INFO]\tResult from SMSW:[0x%04x]\n", msw1); printf("[INFO]\tResult from SIDT: limit[0x%04x]base[0x%08lx]\n", idt1.limit, idt1.base); printf("[INFO]\tResult from SGDT: limit[0x%04x]base[0x%08lx]\n", gdt1.limit, gdt1.base); if (msw1 != msw2 || msw1 != msw3) printf("[FAIL]\tAll the results of SMSW should be the same.\n"); else printf("[PASS]\tAll the results from SMSW are identical.\n"); if (memcmp(&gdt1, &gdt2, sizeof(gdt1))) printf("[FAIL]\tAll the results of SGDT should be the same.\n"); else printf("[PASS]\tAll the results from SGDT are identical.\n"); if (memcmp(&idt1, &idt2, sizeof(idt1))) printf("[FAIL]\tAll the results of SIDT should be the same.\n"); else printf("[PASS]\tAll the results from SIDT are identical.\n"); sethandler(SIGILL, sighandler, 0); do_test(vm86, vmcode_umip_str - vmcode, VM86_SIGNAL, 0, "STR instruction"); clearhandler(SIGILL); sethandler(SIGILL, sighandler, 0); do_test(vm86, vmcode_umip_sldt - vmcode, VM86_SIGNAL, 0, "SLDT instruction"); clearhandler(SIGILL); } int main(void) { struct vm86plus_struct v86; unsigned char *addr = mmap((void *)load_addr, 4096, PROT_READ | PROT_WRITE | PROT_EXEC, MAP_ANONYMOUS | MAP_PRIVATE, -1,0); if (addr != (unsigned char *)load_addr) err(1, "mmap"); memcpy(addr, vmcode, end_vmcode - vmcode); addr[2048] = 2; addr[2050] = 3; memset(&v86, 0, sizeof(v86)); v86.regs.cs = load_addr / 16; v86.regs.ss = load_addr / 16; v86.regs.ds = load_addr / 16; v86.regs.es = load_addr / 16; /* Use the end of the page as our stack. */ v86.regs.esp = 4096; assert((v86.regs.cs & 3) == 0); /* Looks like RPL = 0 */ /* #BR -- should deliver SIG??? */ do_test(&v86, vmcode_bound - vmcode, VM86_INTx, 5, "#BR"); /* * SYSENTER -- should cause #GP or #UD depending on CPU. * Expected return type -1 means that we shouldn't validate * the vm86 return value. This will avoid problems on non-SEP * CPUs. */ sethandler(SIGILL, sighandler, 0); do_test(&v86, vmcode_sysenter - vmcode, -1, 0, "SYSENTER"); clearhandler(SIGILL); /* * SYSCALL would be a disaster in VM86 mode. Fortunately, * there is no kernel that both enables SYSCALL and sets * EFER.SCE, so it's #UD on all systems. But vm86 is * buggy (or has a "feature"), so the SIGILL will actually * be delivered. */ sethandler(SIGILL, sighandler, 0); do_test(&v86, vmcode_syscall - vmcode, VM86_SIGNAL, 0, "SYSCALL"); clearhandler(SIGILL); /* STI with VIP set */ v86.regs.eflags |= X86_EFLAGS_VIP; v86.regs.eflags &= ~X86_EFLAGS_IF; do_test(&v86, vmcode_sti - vmcode, VM86_STI, 0, "STI with VIP set"); /* POPF with VIP set but IF clear: should not trap */ v86.regs.eflags = X86_EFLAGS_VIP; v86.regs.eax = 0; do_test(&v86, vmcode_popf_hlt - vmcode, VM86_UNKNOWN, 0, "POPF with VIP set and IF clear"); /* POPF with VIP set and IF set: should trap */ v86.regs.eflags = X86_EFLAGS_VIP; v86.regs.eax = X86_EFLAGS_IF; do_test(&v86, vmcode_popf_hlt - vmcode, VM86_STI, 0, "POPF with VIP and IF set"); /* POPF with VIP clear and IF set: should not trap */ v86.regs.eflags = 0; v86.regs.eax = X86_EFLAGS_IF; do_test(&v86, vmcode_popf_hlt - vmcode, VM86_UNKNOWN, 0, "POPF with VIP clear and IF set"); v86.regs.eflags = 0; /* INT3 -- should cause #BP */ do_test(&v86, vmcode_int3 - vmcode, VM86_TRAP, 3, "INT3"); /* INT80 -- should exit with "INTx 0x80" */ v86.regs.eax = (unsigned int)-1; do_test(&v86, vmcode_int80 - vmcode, VM86_INTx, 0x80, "int80"); /* UMIP -- should exit with INTx 0x80 unless UMIP was not disabled */ do_umip_tests(&v86, addr); /* Execute a null pointer */ v86.regs.cs = 0; v86.regs.ss = 0; sethandler(SIGSEGV, sighandler, 0); got_signal = 0; if (do_test(&v86, 0, VM86_SIGNAL, 0, "Execute null pointer") && !got_signal) { printf("[FAIL]\tDid not receive SIGSEGV\n"); nerrs++; } clearhandler(SIGSEGV); /* Make sure nothing explodes if we fork. */ if (fork() == 0) return 0; return (nerrs == 0 ? 0 : 1); }