// Copyright (c) 2013 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
// Note: any code in this file MUST be async-signal safe.
#include "sandbox/linux/seccomp-bpf-helpers/sigsys_handlers.h"
#include <sys/syscall.h>
#include <unistd.h>
#include "base/basictypes.h"
#include "base/logging.h"
#include "base/posix/eintr_wrapper.h"
#include "build/build_config.h"
#include "sandbox/linux/seccomp-bpf/sandbox_bpf.h"
#include "sandbox/linux/seccomp-bpf/syscall.h"
#include "sandbox/linux/services/linux_syscalls.h"
#if defined(__mips__)
// __NR_Linux, is defined in <asm/unistd.h>.
#include <asm/unistd.h>
#endif
#define SECCOMP_MESSAGE_COMMON_CONTENT "seccomp-bpf failure"
#define SECCOMP_MESSAGE_CLONE_CONTENT "clone() failure"
#define SECCOMP_MESSAGE_PRCTL_CONTENT "prctl() failure"
#define SECCOMP_MESSAGE_IOCTL_CONTENT "ioctl() failure"
#define SECCOMP_MESSAGE_KILL_CONTENT "(tg)kill() failure"
#define SECCOMP_MESSAGE_FUTEX_CONTENT "futex() failure"
namespace {
inline bool IsArchitectureX86_64() {
#if defined(__x86_64__)
return true;
#else
return false;
#endif
}
// Write |error_message| to stderr. Similar to RawLog(), but a bit more careful
// about async-signal safety. |size| is the size to write and should typically
// not include a terminating \0.
void WriteToStdErr(const char* error_message, size_t size) {
while (size > 0) {
// TODO(jln): query the current policy to check if send() is available and
// use it to perform a non-blocking write.
const int ret = HANDLE_EINTR(write(STDERR_FILENO, error_message, size));
// We can't handle any type of error here.
if (ret <= 0 || static_cast<size_t>(ret) > size) break;
size -= ret;
error_message += ret;
}
}
// Invalid syscall values are truncated to zero.
// On architectures where base value is zero (Intel and Arm),
// syscall number is the same as offset from base.
// This function returns values between 0 and 1023 on all architectures.
// On architectures where base value is different than zero (currently only
// Mips), we are truncating valid syscall values to offset from base.
uint32_t SyscallNumberToOffsetFromBase(uint32_t sysno) {
#if defined(__mips__)
// On MIPS syscall numbers are in different range than on x86 and ARM.
// Valid MIPS O32 ABI syscall __NR_syscall will be truncated to zero for
// simplicity.
sysno = sysno - __NR_Linux;
#endif
if (sysno >= 1024)
sysno = 0;
return sysno;
}
// Print a seccomp-bpf failure to handle |sysno| to stderr in an
// async-signal safe way.
void PrintSyscallError(uint32_t sysno) {
if (sysno >= 1024)
sysno = 0;
// TODO(markus): replace with async-signal safe snprintf when available.
const size_t kNumDigits = 4;
char sysno_base10[kNumDigits];
uint32_t rem = sysno;
uint32_t mod = 0;
for (int i = kNumDigits - 1; i >= 0; i--) {
mod = rem % 10;
rem /= 10;
sysno_base10[i] = '0' + mod;
}
#if defined(__mips__) && (_MIPS_SIM == _MIPS_SIM_ABI32)
static const char kSeccompErrorPrefix[] = __FILE__
":**CRASHING**:" SECCOMP_MESSAGE_COMMON_CONTENT " in syscall 4000 + ";
#else
static const char kSeccompErrorPrefix[] =
__FILE__":**CRASHING**:" SECCOMP_MESSAGE_COMMON_CONTENT " in syscall ";
#endif
static const char kSeccompErrorPostfix[] = "\n";
WriteToStdErr(kSeccompErrorPrefix, sizeof(kSeccompErrorPrefix) - 1);
WriteToStdErr(sysno_base10, sizeof(sysno_base10));
WriteToStdErr(kSeccompErrorPostfix, sizeof(kSeccompErrorPostfix) - 1);
}
} // namespace.
namespace sandbox {
intptr_t CrashSIGSYS_Handler(const struct arch_seccomp_data& args, void* aux) {
uint32_t syscall = SyscallNumberToOffsetFromBase(args.nr);
PrintSyscallError(syscall);
// Encode 8-bits of the 1st two arguments too, so we can discern which socket
// type, which fcntl, ... etc., without being likely to hit a mapped
// address.
// Do not encode more bits here without thinking about increasing the
// likelihood of collision with mapped pages.
syscall |= ((args.args[0] & 0xffUL) << 12);
syscall |= ((args.args[1] & 0xffUL) << 20);
// Purposefully dereference the syscall as an address so it'll show up very
// clearly and easily in crash dumps.
volatile char* addr = reinterpret_cast<volatile char*>(syscall);
*addr = '\0';
// In case we hit a mapped address, hit the null page with just the syscall,
// for paranoia.
syscall &= 0xfffUL;
addr = reinterpret_cast<volatile char*>(syscall);
*addr = '\0';
for (;;)
_exit(1);
}
// TODO(jln): refactor the reporting functions.
intptr_t SIGSYSCloneFailure(const struct arch_seccomp_data& args, void* aux) {
static const char kSeccompCloneError[] =
__FILE__":**CRASHING**:" SECCOMP_MESSAGE_CLONE_CONTENT "\n";
WriteToStdErr(kSeccompCloneError, sizeof(kSeccompCloneError) - 1);
// "flags" is the first argument in the kernel's clone().
// Mark as volatile to be able to find the value on the stack in a minidump.
volatile uint64_t clone_flags = args.args[0];
volatile char* addr;
if (IsArchitectureX86_64()) {
addr = reinterpret_cast<volatile char*>(clone_flags & 0xFFFFFF);
*addr = '\0';
}
// Hit the NULL page if this fails to fault.
addr = reinterpret_cast<volatile char*>(clone_flags & 0xFFF);
*addr = '\0';
for (;;)
_exit(1);
}
intptr_t SIGSYSPrctlFailure(const struct arch_seccomp_data& args,
void* /* aux */) {
static const char kSeccompPrctlError[] =
__FILE__":**CRASHING**:" SECCOMP_MESSAGE_PRCTL_CONTENT "\n";
WriteToStdErr(kSeccompPrctlError, sizeof(kSeccompPrctlError) - 1);
// Mark as volatile to be able to find the value on the stack in a minidump.
volatile uint64_t option = args.args[0];
volatile char* addr =
reinterpret_cast<volatile char*>(option & 0xFFF);
*addr = '\0';
for (;;)
_exit(1);
}
intptr_t SIGSYSIoctlFailure(const struct arch_seccomp_data& args,
void* /* aux */) {
static const char kSeccompIoctlError[] =
__FILE__":**CRASHING**:" SECCOMP_MESSAGE_IOCTL_CONTENT "\n";
WriteToStdErr(kSeccompIoctlError, sizeof(kSeccompIoctlError) - 1);
// Make "request" volatile so that we can see it on the stack in a minidump.
volatile uint64_t request = args.args[1];
volatile char* addr = reinterpret_cast<volatile char*>(request & 0xFFFF);
*addr = '\0';
// Hit the NULL page if this fails.
addr = reinterpret_cast<volatile char*>(request & 0xFFF);
*addr = '\0';
for (;;)
_exit(1);
}
intptr_t SIGSYSKillFailure(const struct arch_seccomp_data& args,
void* /* aux */) {
static const char kSeccompKillError[] =
__FILE__":**CRASHING**:" SECCOMP_MESSAGE_KILL_CONTENT "\n";
WriteToStdErr(kSeccompKillError, sizeof(kSeccompKillError) - 1);
// Make "request" volatile so that we can see it on the stack in a minidump.
volatile uint64_t pid = args.args[0];
volatile char* addr = reinterpret_cast<volatile char*>(pid & 0xFFF);
*addr = '\0';
// Hit the NULL page if this fails.
addr = reinterpret_cast<volatile char*>(pid & 0xFFF);
*addr = '\0';
for (;;)
_exit(1);
}
intptr_t SIGSYSFutexFailure(const struct arch_seccomp_data& args,
void* /* aux */) {
static const char kSeccompFutexError[] =
__FILE__ ":**CRASHING**:" SECCOMP_MESSAGE_FUTEX_CONTENT "\n";
WriteToStdErr(kSeccompFutexError, sizeof(kSeccompFutexError) - 1);
volatile int futex_op = args.args[1];
volatile char* addr = reinterpret_cast<volatile char*>(futex_op & 0xFFF);
*addr = '\0';
for (;;)
_exit(1);
}
intptr_t SIGSYSSchedHandler(const struct arch_seccomp_data& args,
void* aux) {
switch (args.nr) {
case __NR_sched_getaffinity:
case __NR_sched_getattr:
case __NR_sched_getparam:
case __NR_sched_getscheduler:
case __NR_sched_rr_get_interval:
case __NR_sched_setaffinity:
case __NR_sched_setattr:
case __NR_sched_setparam:
case __NR_sched_setscheduler:
const pid_t tid = syscall(__NR_gettid);
// The first argument is the pid. If is our thread id, then replace it
// with 0, which is equivalent and allowed by the policy.
if (args.args[0] == static_cast<uint64_t>(tid)) {
return Syscall::Call(args.nr,
0,
static_cast<intptr_t>(args.args[1]),
static_cast<intptr_t>(args.args[2]),
static_cast<intptr_t>(args.args[3]),
static_cast<intptr_t>(args.args[4]),
static_cast<intptr_t>(args.args[5]));
}
break;
}
CrashSIGSYS_Handler(args, aux);
// Should never be reached.
RAW_CHECK(false);
return -ENOSYS;
}
bpf_dsl::ResultExpr CrashSIGSYS() {
return bpf_dsl::Trap(CrashSIGSYS_Handler, NULL);
}
bpf_dsl::ResultExpr CrashSIGSYSClone() {
return bpf_dsl::Trap(SIGSYSCloneFailure, NULL);
}
bpf_dsl::ResultExpr CrashSIGSYSPrctl() {
return bpf_dsl::Trap(SIGSYSPrctlFailure, NULL);
}
bpf_dsl::ResultExpr CrashSIGSYSIoctl() {
return bpf_dsl::Trap(SIGSYSIoctlFailure, NULL);
}
bpf_dsl::ResultExpr CrashSIGSYSKill() {
return bpf_dsl::Trap(SIGSYSKillFailure, NULL);
}
bpf_dsl::ResultExpr CrashSIGSYSFutex() {
return bpf_dsl::Trap(SIGSYSFutexFailure, NULL);
}
bpf_dsl::ResultExpr RewriteSchedSIGSYS() {
return bpf_dsl::Trap(SIGSYSSchedHandler, NULL);
}
const char* GetErrorMessageContentForTests() {
return SECCOMP_MESSAGE_COMMON_CONTENT;
}
const char* GetCloneErrorMessageContentForTests() {
return SECCOMP_MESSAGE_CLONE_CONTENT;
}
const char* GetPrctlErrorMessageContentForTests() {
return SECCOMP_MESSAGE_PRCTL_CONTENT;
}
const char* GetIoctlErrorMessageContentForTests() {
return SECCOMP_MESSAGE_IOCTL_CONTENT;
}
const char* GetKillErrorMessageContentForTests() {
return SECCOMP_MESSAGE_KILL_CONTENT;
}
const char* GetFutexErrorMessageContentForTests() {
return SECCOMP_MESSAGE_FUTEX_CONTENT;
}
} // namespace sandbox.