sandbox/linux/seccomp-bpf/trap.cc - chromium/src - Git at Google

 // Copyright (c) 2012 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.

 #include "sandbox/linux/seccomp-bpf/trap.h"

 #include <errno.h>
 #include <signal.h>
 #include <stddef.h>
 #include <stdint.h>
 #include <string.h>
 #include <sys/syscall.h>

 #include <algorithm>
 #include <limits>
 #include <tuple>

 #include "base/compiler_specific.h"
 #include "base/logging.h"
 #include "build/build_config.h"
 #include "sandbox/linux/bpf_dsl/seccomp_macros.h"
 #include "sandbox/linux/seccomp-bpf/die.h"
 #include "sandbox/linux/seccomp-bpf/syscall.h"
 #include "sandbox/linux/services/syscall_wrappers.h"
 #include "sandbox/linux/system_headers/linux_seccomp.h"
 #include "sandbox/linux/system_headers/linux_signal.h"

 namespace {

 struct arch_sigsys {
   void* ip;
   int nr;
   unsigned int arch;
 };

 const int kCapacityIncrement = 20;

 // Unsafe traps can only be turned on, if the user explicitly allowed them
 // by setting the CHROME_SANDBOX_DEBUGGING environment variable.
 const char kSandboxDebuggingEnv[] = "CHROME_SANDBOX_DEBUGGING";

 // We need to tell whether we are performing a "normal" callback, or
 // whether we were called recursively from within a UnsafeTrap() callback.
 // This is a little tricky to do, because we need to somehow get access to
 // per-thread data from within a signal context. Normal TLS storage is not
 // safely accessible at this time. We could roll our own, but that involves
 // a lot of complexity. Instead, we co-opt one bit in the signal mask.
 // If BUS is blocked, we assume that we have been called recursively.
 // There is a possibility for collision with other code that needs to do
 // this, but in practice the risks are low.
 // If SIGBUS turns out to be a problem, we could instead co-opt one of the
 // realtime signals. There are plenty of them. Unfortunately, there is no
 // way to mark a signal as allocated. So, the potential for collision is
 // possibly even worse.
 bool GetIsInSigHandler(const ucontext_t* ctx) {
   // Note: on Android, sigismember does not take a pointer to const.
   return sigismember(const_cast<sigset_t*>(&ctx->uc_sigmask), LINUX_SIGBUS);
 }

 void SetIsInSigHandler() {
   sigset_t mask;
   if (sigemptyset(&mask) || sigaddset(&mask, LINUX_SIGBUS) ||
       sandbox::sys_sigprocmask(LINUX_SIG_BLOCK, &mask, NULL)) {
     SANDBOX_DIE("Failed to block SIGBUS");
   }
 }

 bool IsDefaultSignalAction(const struct sigaction& sa) {
   if (sa.sa_flags & SA_SIGINFO || sa.sa_handler != SIG_DFL) {
     return false;
   }
   return true;
 }

 }  // namespace

 namespace sandbox {

 Trap::Trap()
     : trap_array_(NULL),
       trap_array_size_(0),
       trap_array_capacity_(0),
       has_unsafe_traps_(false) {
   // Set new SIGSYS handler
   struct sigaction sa = {};
   // In some toolchain, sa_sigaction is not declared in struct sigaction.
   // So, here cast the pointer to the sa_handler's type. This works because
   // |sa_handler| and |sa_sigaction| shares the same memory.
   sa.sa_handler = reinterpret_cast<void (*)(int)>(SigSysAction);
   sa.sa_flags = LINUX_SA_SIGINFO | LINUX_SA_NODEFER;
   struct sigaction old_sa = {};
   if (sys_sigaction(LINUX_SIGSYS, &sa, &old_sa) < 0) {
     SANDBOX_DIE("Failed to configure SIGSYS handler");
   }

   if (!IsDefaultSignalAction(old_sa)) {
     static const char kExistingSIGSYSMsg[] =
         "Existing signal handler when trying to install SIGSYS. SIGSYS needs "
         "to be reserved for seccomp-bpf.";
     DLOG(FATAL) << kExistingSIGSYSMsg;
     LOG(ERROR) << kExistingSIGSYSMsg;
   }

   // Unmask SIGSYS
   sigset_t mask;
   if (sigemptyset(&mask) || sigaddset(&mask, LINUX_SIGSYS) ||
       sys_sigprocmask(LINUX_SIG_UNBLOCK, &mask, NULL)) {
     SANDBOX_DIE("Failed to configure SIGSYS handler");
   }
 }

 bpf_dsl::TrapRegistry* Trap::Registry() {
   // Note: This class is not thread safe. It is the caller's responsibility
   // to avoid race conditions. Normally, this is a non-issue as the sandbox
   // can only be initialized if there are no other threads present.
   // Also, this is not a normal singleton. Once created, the global trap
   // object must never be destroyed again.
   if (!global_trap_) {
     global_trap_ = new Trap();
     if (!global_trap_) {
       SANDBOX_DIE("Failed to allocate global trap handler");
     }
   }
   return global_trap_;
 }

 void Trap::SigSysAction(int nr, LinuxSigInfo* info, void* void_context) {
   if (info) {
     MSAN_UNPOISON(info, sizeof(*info));
   }

   // Obtain the signal context. This, most notably, gives us access to
   // all CPU registers at the time of the signal.
   ucontext_t* ctx = reinterpret_cast<ucontext_t*>(void_context);
   if (ctx) {
     MSAN_UNPOISON(ctx, sizeof(*ctx));
   }

   if (!global_trap_) {
     RAW_SANDBOX_DIE(
         "This can't happen. Found no global singleton instance "
         "for Trap() handling.");
   }
   global_trap_->SigSys(nr, info, ctx);
 }

 void Trap::SigSys(int nr, LinuxSigInfo* info, ucontext_t* ctx) {
   // Signal handlers should always preserve "errno". Otherwise, we could
   // trigger really subtle bugs.
   const int old_errno = errno;

   // Various sanity checks to make sure we actually received a signal
   // triggered by a BPF filter. If something else triggered SIGSYS
   // (e.g. kill()), there is really nothing we can do with this signal.
   if (nr != LINUX_SIGSYS || info->si_code != SYS_SECCOMP || !ctx ||
       info->si_errno <= 0 ||
       static_cast<size_t>(info->si_errno) > trap_array_size_) {
     // ATI drivers seem to send SIGSYS, so this cannot be FATAL.
     // See crbug.com/178166.
     // TODO(jln): add a DCHECK or move back to FATAL.
     RAW_LOG(ERROR, "Unexpected SIGSYS received.");
     errno = old_errno;
     return;
   }


   // Obtain the siginfo information that is specific to SIGSYS. Unfortunately,
   // most versions of glibc don't include this information in siginfo_t. So,
   // we need to explicitly copy it into a arch_sigsys structure.
   struct arch_sigsys sigsys;
   memcpy(&sigsys, &info->_sifields, sizeof(sigsys));

 #if defined(__mips__)
   // When indirect syscall (syscall(__NR_foo, ...)) is made on Mips, the
   // number in register SECCOMP_SYSCALL(ctx) is always __NR_syscall and the
   // real number of a syscall (__NR_foo) is in SECCOMP_PARM1(ctx)
   bool sigsys_nr_is_bad = sigsys.nr != static_cast<int>(SECCOMP_SYSCALL(ctx)) &&
                           sigsys.nr != static_cast<int>(SECCOMP_PARM1(ctx));
 #else
   bool sigsys_nr_is_bad = sigsys.nr != static_cast<int>(SECCOMP_SYSCALL(ctx));
 #endif

   // Some more sanity checks.
   if (sigsys.ip != reinterpret_cast<void*>(SECCOMP_IP(ctx)) ||
       sigsys_nr_is_bad || sigsys.arch != SECCOMP_ARCH) {
     // TODO(markus):
     // SANDBOX_DIE() can call LOG(FATAL). This is not normally async-signal
     // safe and can lead to bugs. We should eventually implement a different
     // logging and reporting mechanism that is safe to be called from
     // the sigSys() handler.
     RAW_SANDBOX_DIE("Sanity checks are failing after receiving SIGSYS.");
   }

   intptr_t rc;
   if (has_unsafe_traps_ && GetIsInSigHandler(ctx)) {
     errno = old_errno;
     if (sigsys.nr == __NR_clone) {
       RAW_SANDBOX_DIE("Cannot call clone() from an UnsafeTrap() handler.");
     }
 #if defined(__mips__)
     // Mips supports up to eight arguments for syscall.
     // However, seccomp bpf can filter only up to six arguments, so using eight
     // arguments has sense only when using UnsafeTrap() handler.
     rc = Syscall::Call(SECCOMP_SYSCALL(ctx),
                        SECCOMP_PARM1(ctx),
                        SECCOMP_PARM2(ctx),
                        SECCOMP_PARM3(ctx),
                        SECCOMP_PARM4(ctx),
                        SECCOMP_PARM5(ctx),
                        SECCOMP_PARM6(ctx),
                        SECCOMP_PARM7(ctx),
                        SECCOMP_PARM8(ctx));
 #else
     rc = Syscall::Call(SECCOMP_SYSCALL(ctx),
                        SECCOMP_PARM1(ctx),
                        SECCOMP_PARM2(ctx),
                        SECCOMP_PARM3(ctx),
                        SECCOMP_PARM4(ctx),
                        SECCOMP_PARM5(ctx),
                        SECCOMP_PARM6(ctx));
 #endif  // defined(__mips__)
   } else {
     const TrapKey& trap = trap_array_[info->si_errno - 1];
     if (!trap.safe) {
       SetIsInSigHandler();
     }

     // Copy the seccomp-specific data into a arch_seccomp_data structure. This
     // is what we are showing to TrapFnc callbacks that the system call
     // evaluator registered with the sandbox.
     struct arch_seccomp_data data = {
         static_cast<int>(SECCOMP_SYSCALL(ctx)),
         SECCOMP_ARCH,
         reinterpret_cast<uint64_t>(sigsys.ip),
         {static_cast<uint64_t>(SECCOMP_PARM1(ctx)),
          static_cast<uint64_t>(SECCOMP_PARM2(ctx)),
          static_cast<uint64_t>(SECCOMP_PARM3(ctx)),
          static_cast<uint64_t>(SECCOMP_PARM4(ctx)),
          static_cast<uint64_t>(SECCOMP_PARM5(ctx)),
          static_cast<uint64_t>(SECCOMP_PARM6(ctx))}};

     // Now call the TrapFnc callback associated with this particular instance
     // of SECCOMP_RET_TRAP.
     rc = trap.fnc(data, const_cast<void*>(trap.aux));
   }

   // Update the CPU register that stores the return code of the system call
   // that we just handled, and restore "errno" to the value that it had
   // before entering the signal handler.
   Syscall::PutValueInUcontext(rc, ctx);
   errno = old_errno;

   return;
 }

 bool Trap::TrapKey::operator<(const TrapKey& o) const {
   return std::tie(fnc, aux, safe) < std::tie(o.fnc, o.aux, o.safe);
 }

 uint16_t Trap::Add(TrapFnc fnc, const void* aux, bool safe) {
   if (!safe && !SandboxDebuggingAllowedByUser()) {
     // Unless the user set the CHROME_SANDBOX_DEBUGGING environment variable,
     // we never return an ErrorCode that is marked as "unsafe". This also
     // means, the BPF compiler will never emit code that allow unsafe system
     // calls to by-pass the filter (because they use the magic return address
     // from Syscall::Call(-1)).

     // This SANDBOX_DIE() can optionally be removed. It won't break security,
     // but it might make error messages from the BPF compiler a little harder
     // to understand. Removing the SANDBOX_DIE() allows callers to easily check
     // whether unsafe traps are supported (by checking whether the returned
     // ErrorCode is ET_INVALID).
     SANDBOX_DIE(
         "Cannot use unsafe traps unless CHROME_SANDBOX_DEBUGGING "
         "is enabled");

     return 0;
   }

   // Each unique pair of TrapFnc and auxiliary data make up a distinct instance
   // of a SECCOMP_RET_TRAP.
   TrapKey key(fnc, aux, safe);

   // We return unique identifiers together with SECCOMP_RET_TRAP. This allows
   // us to associate trap with the appropriate handler. The kernel allows us
   // identifiers in the range from 0 to SECCOMP_RET_DATA (0xFFFF). We want to
   // avoid 0, as it could be confused for a trap without any specific id.
   // The nice thing about sequentially numbered identifiers is that we can also
   // trivially look them up from our signal handler without making any system
   // calls that might be async-signal-unsafe.
   // In order to do so, we store all of our traps in a C-style trap_array_.

   TrapIds::const_iterator iter = trap_ids_.find(key);
   if (iter != trap_ids_.end()) {
     // We have seen this pair before. Return the same id that we assigned
     // earlier.
     return iter->second;
   }

   // This is a new pair. Remember it and assign a new id.
   if (trap_array_size_ >= SECCOMP_RET_DATA /* 0xFFFF */ ||
       trap_array_size_ >= std::numeric_limits<uint16_t>::max()) {
     // In practice, this is pretty much impossible to trigger, as there
     // are other kernel limitations that restrict overall BPF program sizes.
     SANDBOX_DIE("Too many SECCOMP_RET_TRAP callback instances");
   }

   // Our callers ensure that there are no other threads accessing trap_array_
   // concurrently (typically this is done by ensuring that we are single-
   // threaded while the sandbox is being set up). But we nonetheless are
   // modifying a live data structure that could be accessed any time a
   // system call is made; as system calls could be triggering SIGSYS.
   // So, we have to be extra careful that we update trap_array_ atomically.
   // In particular, this means we shouldn't be using realloc() to resize it.
   // Instead, we allocate a new array, copy the values, and then switch the
   // pointer. We only really care about the pointer being updated atomically
   // and the data that is pointed to being valid, as these are the only
   // values accessed from the signal handler. It is OK if trap_array_size_
   // is inconsistent with the pointer, as it is monotonously increasing.
   // Also, we only care about compiler barriers, as the signal handler is
   // triggered synchronously from a system call. We don't have to protect
   // against issues with the memory model or with completely asynchronous
   // events.
   if (trap_array_size_ >= trap_array_capacity_) {
     trap_array_capacity_ += kCapacityIncrement;
     TrapKey* old_trap_array = trap_array_;
     TrapKey* new_trap_array = new TrapKey[trap_array_capacity_];
     std::copy_n(old_trap_array, trap_array_size_, new_trap_array);

     // Language specs are unclear on whether the compiler is allowed to move
     // the "delete[]" above our preceding assignments and/or memory moves,
     // iff the compiler believes that "delete[]" doesn't have any other
     // global side-effects.
     // We insert optimization barriers to prevent this from happening.
     // The first barrier is probably not needed, but better be explicit in
     // what we want to tell the compiler.
     // The clang developer mailing list couldn't answer whether this is a
     // legitimate worry; but they at least thought that the barrier is
     // sufficient to prevent the (so far hypothetical) problem of re-ordering
     // of instructions by the compiler.
     //
     // TODO(mdempsky): Try to clean this up using base/atomicops or C++11
     // atomics; see crbug.com/414363.
     asm volatile("" : "=r"(new_trap_array) : "0"(new_trap_array) : "memory");
     trap_array_ = new_trap_array;
     asm volatile("" : "=r"(trap_array_) : "0"(trap_array_) : "memory");

     delete[] old_trap_array;
   }

   uint16_t id = trap_array_size_ + 1;
   trap_ids_[key] = id;
   trap_array_[trap_array_size_] = key;
   trap_array_size_++;
   return id;
 }

 bool Trap::SandboxDebuggingAllowedByUser() {
   const char* debug_flag = getenv(kSandboxDebuggingEnv);
   return debug_flag && *debug_flag;
 }

 bool Trap::EnableUnsafeTraps() {
   if (!has_unsafe_traps_) {
     // Unsafe traps are a one-way fuse. Once enabled, they can never be turned
     // off again.
     // We only allow enabling unsafe traps, if the user explicitly set an
     // appropriate environment variable. This prevents bugs that accidentally
     // disable all sandboxing for all users.
     if (SandboxDebuggingAllowedByUser()) {
       // We only ever print this message once, when we enable unsafe traps the
       // first time.
       SANDBOX_INFO("WARNING! Disabling sandbox for debugging purposes");
       has_unsafe_traps_ = true;
     } else {
       SANDBOX_INFO(
           "Cannot disable sandbox and use unsafe traps unless "
           "CHROME_SANDBOX_DEBUGGING is turned on first");
     }
   }
   // Returns the, possibly updated, value of has_unsafe_traps_.
   return has_unsafe_traps_;
 }

 Trap* Trap::global_trap_;

 }  // namespace sandbox
	// Copyright (c) 2012 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.

	#include "sandbox/linux/seccomp-bpf/trap.h"

	#include <errno.h>
	#include <signal.h>
	#include <stddef.h>
	#include <stdint.h>
	#include <string.h>
	#include <sys/syscall.h>

	#include <algorithm>
	#include <limits>
	#include <tuple>

	#include "base/compiler_specific.h"
	#include "base/logging.h"
	#include "build/build_config.h"
	#include "sandbox/linux/bpf_dsl/seccomp_macros.h"
	#include "sandbox/linux/seccomp-bpf/die.h"
	#include "sandbox/linux/seccomp-bpf/syscall.h"
	#include "sandbox/linux/services/syscall_wrappers.h"
	#include "sandbox/linux/system_headers/linux_seccomp.h"
	#include "sandbox/linux/system_headers/linux_signal.h"

	namespace {

	struct arch_sigsys {
	void* ip;
	int nr;
	unsigned int arch;
	};

	const int kCapacityIncrement = 20;

	// Unsafe traps can only be turned on, if the user explicitly allowed them
	// by setting the CHROME_SANDBOX_DEBUGGING environment variable.
	const char kSandboxDebuggingEnv[] = "CHROME_SANDBOX_DEBUGGING";

	// We need to tell whether we are performing a "normal" callback, or
	// whether we were called recursively from within a UnsafeTrap() callback.
	// This is a little tricky to do, because we need to somehow get access to
	// per-thread data from within a signal context. Normal TLS storage is not
	// safely accessible at this time. We could roll our own, but that involves
	// a lot of complexity. Instead, we co-opt one bit in the signal mask.
	// If BUS is blocked, we assume that we have been called recursively.
	// There is a possibility for collision with other code that needs to do
	// this, but in practice the risks are low.
	// If SIGBUS turns out to be a problem, we could instead co-opt one of the
	// realtime signals. There are plenty of them. Unfortunately, there is no
	// way to mark a signal as allocated. So, the potential for collision is
	// possibly even worse.
	bool GetIsInSigHandler(const ucontext_t* ctx) {
	// Note: on Android, sigismember does not take a pointer to const.
	return sigismember(const_cast<sigset_t*>(&ctx->uc_sigmask), LINUX_SIGBUS);
	}

	void SetIsInSigHandler() {
	sigset_t mask;
	if (sigemptyset(&mask) \|\| sigaddset(&mask, LINUX_SIGBUS) \|\|
	sandbox::sys_sigprocmask(LINUX_SIG_BLOCK, &mask, NULL)) {
	SANDBOX_DIE("Failed to block SIGBUS");
	}
	}

	bool IsDefaultSignalAction(const struct sigaction& sa) {
	if (sa.sa_flags & SA_SIGINFO \|\| sa.sa_handler != SIG_DFL) {
	return false;
	}
	return true;
	}

	} // namespace

	namespace sandbox {

	Trap::Trap()
	: trap_array_(NULL),
	trap_array_size_(0),
	trap_array_capacity_(0),
	has_unsafe_traps_(false) {
	// Set new SIGSYS handler
	struct sigaction sa = {};
	// In some toolchain, sa_sigaction is not declared in struct sigaction.
	// So, here cast the pointer to the sa_handler's type. This works because
	// \|sa_handler\| and \|sa_sigaction\| shares the same memory.
	sa.sa_handler = reinterpret_cast<void (*)(int)>(SigSysAction);
	sa.sa_flags = LINUX_SA_SIGINFO \| LINUX_SA_NODEFER;
	struct sigaction old_sa = {};
	if (sys_sigaction(LINUX_SIGSYS, &sa, &old_sa) < 0) {
	SANDBOX_DIE("Failed to configure SIGSYS handler");
	}

	if (!IsDefaultSignalAction(old_sa)) {
	static const char kExistingSIGSYSMsg[] =
	"Existing signal handler when trying to install SIGSYS. SIGSYS needs "
	"to be reserved for seccomp-bpf.";
	DLOG(FATAL) << kExistingSIGSYSMsg;
	LOG(ERROR) << kExistingSIGSYSMsg;
	}

	// Unmask SIGSYS
	sigset_t mask;
	if (sigemptyset(&mask) \|\| sigaddset(&mask, LINUX_SIGSYS) \|\|
	sys_sigprocmask(LINUX_SIG_UNBLOCK, &mask, NULL)) {
	SANDBOX_DIE("Failed to configure SIGSYS handler");
	}
	}

	bpf_dsl::TrapRegistry* Trap::Registry() {
	// Note: This class is not thread safe. It is the caller's responsibility
	// to avoid race conditions. Normally, this is a non-issue as the sandbox
	// can only be initialized if there are no other threads present.
	// Also, this is not a normal singleton. Once created, the global trap
	// object must never be destroyed again.
	if (!global_trap_) {
	global_trap_ = new Trap();
	if (!global_trap_) {
	SANDBOX_DIE("Failed to allocate global trap handler");
	}
	}
	return global_trap_;
	}

	void Trap::SigSysAction(int nr, LinuxSigInfo* info, void* void_context) {
	if (info) {
	MSAN_UNPOISON(info, sizeof(*info));
	}

	// Obtain the signal context. This, most notably, gives us access to
	// all CPU registers at the time of the signal.
	ucontext_t* ctx = reinterpret_cast<ucontext_t*>(void_context);
	if (ctx) {
	MSAN_UNPOISON(ctx, sizeof(*ctx));
	}

	if (!global_trap_) {
	RAW_SANDBOX_DIE(
	"This can't happen. Found no global singleton instance "
	"for Trap() handling.");
	}
	global_trap_->SigSys(nr, info, ctx);
	}

	void Trap::SigSys(int nr, LinuxSigInfo* info, ucontext_t* ctx) {
	// Signal handlers should always preserve "errno". Otherwise, we could
	// trigger really subtle bugs.
	const int old_errno = errno;

	// Various sanity checks to make sure we actually received a signal
	// triggered by a BPF filter. If something else triggered SIGSYS
	// (e.g. kill()), there is really nothing we can do with this signal.
	if (nr != LINUX_SIGSYS \|\| info->si_code != SYS_SECCOMP \|\| !ctx \|\|
	info->si_errno <= 0 \|\|
	static_cast<size_t>(info->si_errno) > trap_array_size_) {
	// ATI drivers seem to send SIGSYS, so this cannot be FATAL.
	// See crbug.com/178166.
	// TODO(jln): add a DCHECK or move back to FATAL.
	RAW_LOG(ERROR, "Unexpected SIGSYS received.");
	errno = old_errno;
	return;
	}


	// Obtain the siginfo information that is specific to SIGSYS. Unfortunately,
	// most versions of glibc don't include this information in siginfo_t. So,
	// we need to explicitly copy it into a arch_sigsys structure.
	struct arch_sigsys sigsys;
	memcpy(&sigsys, &info->_sifields, sizeof(sigsys));

	#if defined(__mips__)
	// When indirect syscall (syscall(__NR_foo, ...)) is made on Mips, the
	// number in register SECCOMP_SYSCALL(ctx) is always __NR_syscall and the
	// real number of a syscall (__NR_foo) is in SECCOMP_PARM1(ctx)
	bool sigsys_nr_is_bad = sigsys.nr != static_cast<int>(SECCOMP_SYSCALL(ctx)) &&
	sigsys.nr != static_cast<int>(SECCOMP_PARM1(ctx));
	#else
	bool sigsys_nr_is_bad = sigsys.nr != static_cast<int>(SECCOMP_SYSCALL(ctx));
	#endif

	// Some more sanity checks.
	if (sigsys.ip != reinterpret_cast<void*>(SECCOMP_IP(ctx)) \|\|
	sigsys_nr_is_bad \|\| sigsys.arch != SECCOMP_ARCH) {
	// TODO(markus):
	// SANDBOX_DIE() can call LOG(FATAL). This is not normally async-signal
	// safe and can lead to bugs. We should eventually implement a different
	// logging and reporting mechanism that is safe to be called from
	// the sigSys() handler.
	RAW_SANDBOX_DIE("Sanity checks are failing after receiving SIGSYS.");
	}

	intptr_t rc;
	if (has_unsafe_traps_ && GetIsInSigHandler(ctx)) {
	errno = old_errno;
	if (sigsys.nr == __NR_clone) {
	RAW_SANDBOX_DIE("Cannot call clone() from an UnsafeTrap() handler.");
	}
	#if defined(__mips__)
	// Mips supports up to eight arguments for syscall.
	// However, seccomp bpf can filter only up to six arguments, so using eight
	// arguments has sense only when using UnsafeTrap() handler.
	rc = Syscall::Call(SECCOMP_SYSCALL(ctx),
	SECCOMP_PARM1(ctx),
	SECCOMP_PARM2(ctx),
	SECCOMP_PARM3(ctx),
	SECCOMP_PARM4(ctx),
	SECCOMP_PARM5(ctx),
	SECCOMP_PARM6(ctx),
	SECCOMP_PARM7(ctx),
	SECCOMP_PARM8(ctx));
	#else
	rc = Syscall::Call(SECCOMP_SYSCALL(ctx),
	SECCOMP_PARM1(ctx),
	SECCOMP_PARM2(ctx),
	SECCOMP_PARM3(ctx),
	SECCOMP_PARM4(ctx),
	SECCOMP_PARM5(ctx),
	SECCOMP_PARM6(ctx));
	#endif // defined(__mips__)
	} else {
	const TrapKey& trap = trap_array_[info->si_errno - 1];
	if (!trap.safe) {
	SetIsInSigHandler();
	}

	// Copy the seccomp-specific data into a arch_seccomp_data structure. This
	// is what we are showing to TrapFnc callbacks that the system call
	// evaluator registered with the sandbox.
	struct arch_seccomp_data data = {
	static_cast<int>(SECCOMP_SYSCALL(ctx)),
	SECCOMP_ARCH,
	reinterpret_cast<uint64_t>(sigsys.ip),
	{static_cast<uint64_t>(SECCOMP_PARM1(ctx)),
	static_cast<uint64_t>(SECCOMP_PARM2(ctx)),
	static_cast<uint64_t>(SECCOMP_PARM3(ctx)),
	static_cast<uint64_t>(SECCOMP_PARM4(ctx)),
	static_cast<uint64_t>(SECCOMP_PARM5(ctx)),
	static_cast<uint64_t>(SECCOMP_PARM6(ctx))}};

	// Now call the TrapFnc callback associated with this particular instance
	// of SECCOMP_RET_TRAP.
	rc = trap.fnc(data, const_cast<void*>(trap.aux));
	}

	// Update the CPU register that stores the return code of the system call
	// that we just handled, and restore "errno" to the value that it had
	// before entering the signal handler.
	Syscall::PutValueInUcontext(rc, ctx);
	errno = old_errno;

	return;
	}

	bool Trap::TrapKey::operator<(const TrapKey& o) const {
	return std::tie(fnc, aux, safe) < std::tie(o.fnc, o.aux, o.safe);
	}

	uint16_t Trap::Add(TrapFnc fnc, const void* aux, bool safe) {
	if (!safe && !SandboxDebuggingAllowedByUser()) {
	// Unless the user set the CHROME_SANDBOX_DEBUGGING environment variable,
	// we never return an ErrorCode that is marked as "unsafe". This also
	// means, the BPF compiler will never emit code that allow unsafe system
	// calls to by-pass the filter (because they use the magic return address
	// from Syscall::Call(-1)).

	// This SANDBOX_DIE() can optionally be removed. It won't break security,
	// but it might make error messages from the BPF compiler a little harder
	// to understand. Removing the SANDBOX_DIE() allows callers to easily check
	// whether unsafe traps are supported (by checking whether the returned
	// ErrorCode is ET_INVALID).
	SANDBOX_DIE(
	"Cannot use unsafe traps unless CHROME_SANDBOX_DEBUGGING "
	"is enabled");

	return 0;
	}

	// Each unique pair of TrapFnc and auxiliary data make up a distinct instance
	// of a SECCOMP_RET_TRAP.
	TrapKey key(fnc, aux, safe);

	// We return unique identifiers together with SECCOMP_RET_TRAP. This allows
	// us to associate trap with the appropriate handler. The kernel allows us
	// identifiers in the range from 0 to SECCOMP_RET_DATA (0xFFFF). We want to
	// avoid 0, as it could be confused for a trap without any specific id.
	// The nice thing about sequentially numbered identifiers is that we can also
	// trivially look them up from our signal handler without making any system
	// calls that might be async-signal-unsafe.
	// In order to do so, we store all of our traps in a C-style trap_array_.

	TrapIds::const_iterator iter = trap_ids_.find(key);
	if (iter != trap_ids_.end()) {
	// We have seen this pair before. Return the same id that we assigned
	// earlier.
	return iter->second;
	}

	// This is a new pair. Remember it and assign a new id.
	if (trap_array_size_ >= SECCOMP_RET_DATA /* 0xFFFF */ \|\|
	trap_array_size_ >= std::numeric_limits<uint16_t>::max()) {
	// In practice, this is pretty much impossible to trigger, as there
	// are other kernel limitations that restrict overall BPF program sizes.
	SANDBOX_DIE("Too many SECCOMP_RET_TRAP callback instances");
	}

	// Our callers ensure that there are no other threads accessing trap_array_
	// concurrently (typically this is done by ensuring that we are single-
	// threaded while the sandbox is being set up). But we nonetheless are
	// modifying a live data structure that could be accessed any time a
	// system call is made; as system calls could be triggering SIGSYS.
	// So, we have to be extra careful that we update trap_array_ atomically.
	// In particular, this means we shouldn't be using realloc() to resize it.
	// Instead, we allocate a new array, copy the values, and then switch the
	// pointer. We only really care about the pointer being updated atomically
	// and the data that is pointed to being valid, as these are the only
	// values accessed from the signal handler. It is OK if trap_array_size_
	// is inconsistent with the pointer, as it is monotonously increasing.
	// Also, we only care about compiler barriers, as the signal handler is
	// triggered synchronously from a system call. We don't have to protect
	// against issues with the memory model or with completely asynchronous
	// events.
	if (trap_array_size_ >= trap_array_capacity_) {
	trap_array_capacity_ += kCapacityIncrement;
	TrapKey* old_trap_array = trap_array_;
	TrapKey* new_trap_array = new TrapKey[trap_array_capacity_];
	std::copy_n(old_trap_array, trap_array_size_, new_trap_array);

	// Language specs are unclear on whether the compiler is allowed to move
	// the "delete[]" above our preceding assignments and/or memory moves,
	// iff the compiler believes that "delete[]" doesn't have any other
	// global side-effects.
	// We insert optimization barriers to prevent this from happening.
	// The first barrier is probably not needed, but better be explicit in
	// what we want to tell the compiler.
	// The clang developer mailing list couldn't answer whether this is a
	// legitimate worry; but they at least thought that the barrier is
	// sufficient to prevent the (so far hypothetical) problem of re-ordering
	// of instructions by the compiler.
	//
	// TODO(mdempsky): Try to clean this up using base/atomicops or C++11
	// atomics; see crbug.com/414363.
	asm volatile("" : "=r"(new_trap_array) : "0"(new_trap_array) : "memory");
	trap_array_ = new_trap_array;
	asm volatile("" : "=r"(trap_array_) : "0"(trap_array_) : "memory");

	delete[] old_trap_array;
	}

	uint16_t id = trap_array_size_ + 1;
	trap_ids_[key] = id;
	trap_array_[trap_array_size_] = key;
	trap_array_size_++;
	return id;
	}

	bool Trap::SandboxDebuggingAllowedByUser() {
	const char* debug_flag = getenv(kSandboxDebuggingEnv);
	return debug_flag && *debug_flag;
	}

	bool Trap::EnableUnsafeTraps() {
	if (!has_unsafe_traps_) {
	// Unsafe traps are a one-way fuse. Once enabled, they can never be turned
	// off again.
	// We only allow enabling unsafe traps, if the user explicitly set an
	// appropriate environment variable. This prevents bugs that accidentally
	// disable all sandboxing for all users.
	if (SandboxDebuggingAllowedByUser()) {
	// We only ever print this message once, when we enable unsafe traps the
	// first time.
	SANDBOX_INFO("WARNING! Disabling sandbox for debugging purposes");
	has_unsafe_traps_ = true;
	} else {
	SANDBOX_INFO(
	"Cannot disable sandbox and use unsafe traps unless "
	"CHROME_SANDBOX_DEBUGGING is turned on first");
	}
	}
	// Returns the, possibly updated, value of has_unsafe_traps_.
	return has_unsafe_traps_;
	}

	Trap* Trap::global_trap_;

	} // namespace sandbox