/* * Copyright 2006 The WebRTC Project Authors. All rights reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #ifndef RTC_BASE_CHECKS_H_ #define RTC_BASE_CHECKS_H_ // If you for some reson need to know if DCHECKs are on, test the value of // RTC_DCHECK_IS_ON. (Test its value, not if it's defined; it'll always be // defined, to either a true or a false value.) #if !defined(NDEBUG) || defined(DCHECK_ALWAYS_ON) #define RTC_DCHECK_IS_ON 1 #else #define RTC_DCHECK_IS_ON 0 #endif // Annotate a function that will not return control flow to the caller. #if defined(_MSC_VER) #define RTC_NORETURN __declspec(noreturn) #elif defined(__GNUC__) #define RTC_NORETURN __attribute__((__noreturn__)) #else #define RTC_NORETURN #endif #ifdef __cplusplus extern "C" { #endif RTC_NORETURN void rtc_FatalMessage(const char* file, int line, const char* msg); #ifdef __cplusplus } // extern "C" #endif #ifdef RTC_DISABLE_CHECK_MSG #define RTC_CHECK_MSG_ENABLED 0 #else #define RTC_CHECK_MSG_ENABLED 1 #endif #if RTC_CHECK_MSG_ENABLED #define RTC_CHECK_EVAL_MESSAGE(message) message #else #define RTC_CHECK_EVAL_MESSAGE(message) "" #endif #ifdef __cplusplus // C++ version. #include #include "absl/meta/type_traits.h" #include "absl/strings/string_view.h" #include "rtc_base/numerics/safe_compare.h" #include "rtc_base/system/inline.h" #include "rtc_base/system/rtc_export.h" // The macros here print a message to stderr and abort under various // conditions. All will accept additional stream messages. For example: // RTC_DCHECK_EQ(foo, bar) << "I'm printed when foo != bar."; // // - RTC_CHECK(x) is an assertion that x is always true, and that if it isn't, // it's better to terminate the process than to continue. During development, // the reason that it's better to terminate might simply be that the error // handling code isn't in place yet; in production, the reason might be that // the author of the code truly believes that x will always be true, but that // they recognizes that if they are wrong, abrupt and unpleasant process // termination is still better than carrying on with the assumption violated. // // RTC_CHECK always evaluates its argument, so it's OK for x to have side // effects. // // - RTC_DCHECK(x) is the same as RTC_CHECK(x)---an assertion that x is always // true---except that x will only be evaluated in debug builds; in production // builds, x is simply assumed to be true. This is useful if evaluating x is // expensive and the expected cost of failing to detect the violated // assumption is acceptable. You should not handle cases where a production // build fails to spot a violated condition, even those that would result in // crashes. If the code needs to cope with the error, make it cope, but don't // call RTC_DCHECK; if the condition really can't occur, but you'd sleep // better at night knowing that the process will suicide instead of carrying // on in case you were wrong, use RTC_CHECK instead of RTC_DCHECK. // // RTC_DCHECK only evaluates its argument in debug builds, so if x has visible // side effects, you need to write e.g. // bool w = x; RTC_DCHECK(w); // // - RTC_CHECK_EQ, _NE, _GT, ..., and RTC_DCHECK_EQ, _NE, _GT, ... are // specialized variants of RTC_CHECK and RTC_DCHECK that print prettier // messages if the condition doesn't hold. Prefer them to raw RTC_CHECK and // RTC_DCHECK. // // - RTC_FATAL() aborts unconditionally. namespace rtc { namespace webrtc_checks_impl { enum class CheckArgType : int8_t { kEnd = 0, kInt, kLong, kLongLong, kUInt, kULong, kULongLong, kDouble, kLongDouble, kCharP, kStdString, kStringView, kVoidP, // kCheckOp doesn't represent an argument type. Instead, it is sent as the // first argument from RTC_CHECK_OP to make FatalLog use the next two // arguments to build the special CHECK_OP error message // (the "a == b (1 vs. 2)" bit). kCheckOp, }; #if RTC_CHECK_MSG_ENABLED RTC_NORETURN RTC_EXPORT void FatalLog(const char* file, int line, const char* message, const CheckArgType* fmt, ...); #else RTC_NORETURN RTC_EXPORT void FatalLog(const char* file, int line); #endif // Wrapper for log arguments. Only ever make values of this type with the // MakeVal() functions. template struct Val { static constexpr CheckArgType Type() { return N; } T GetVal() const { return val; } T val; }; // Case for when we need to construct a temp string and then print that. // (We can't use Val // because we need somewhere to store the temp string.) struct ToStringVal { static constexpr CheckArgType Type() { return CheckArgType::kStdString; } const std::string* GetVal() const { return &val; } std::string val; }; inline Val MakeVal(int x) { return {x}; } inline Val MakeVal(long x) { return {x}; } inline Val MakeVal(long long x) { return {x}; } inline Val MakeVal(unsigned int x) { return {x}; } inline Val MakeVal(unsigned long x) { return {x}; } inline Val MakeVal( unsigned long long x) { return {x}; } inline Val MakeVal(double x) { return {x}; } inline Val MakeVal(long double x) { return {x}; } inline Val MakeVal(const char* x) { return {x}; } inline Val MakeVal( const std::string& x) { return {&x}; } inline Val MakeVal( const absl::string_view& x) { return {&x}; } inline Val MakeVal(const void* x) { return {x}; } // The enum class types are not implicitly convertible to arithmetic types. template ::value && !std::is_arithmetic::value>* = nullptr> inline decltype(MakeVal(std::declval>())) MakeVal( T x) { return {static_cast>(x)}; } template ()))* = nullptr> ToStringVal MakeVal(const T& x) { return {ToLogString(x)}; } // Ephemeral type that represents the result of the logging << operator. template class LogStreamer; // Base case: Before the first << argument. template <> class LogStreamer<> final { public: template ())), absl::enable_if_t::value || std::is_enum::value>* = nullptr> RTC_FORCE_INLINE LogStreamer operator<<(U arg) const { return LogStreamer(MakeVal(arg), this); } template ())), absl::enable_if_t::value && !std::is_enum::value>* = nullptr> RTC_FORCE_INLINE LogStreamer operator<<(const U& arg) const { return LogStreamer(MakeVal(arg), this); } #if RTC_CHECK_MSG_ENABLED template RTC_NORETURN RTC_FORCE_INLINE static void Call(const char* file, const int line, const char* message, const Us&... args) { static constexpr CheckArgType t[] = {Us::Type()..., CheckArgType::kEnd}; FatalLog(file, line, message, t, args.GetVal()...); } template RTC_NORETURN RTC_FORCE_INLINE static void CallCheckOp(const char* file, const int line, const char* message, const Us&... args) { static constexpr CheckArgType t[] = {CheckArgType::kCheckOp, Us::Type()..., CheckArgType::kEnd}; FatalLog(file, line, message, t, args.GetVal()...); } #else template RTC_NORETURN RTC_FORCE_INLINE static void Call(const char* file, const int line) { FatalLog(file, line); } #endif }; // Inductive case: We've already seen at least one << argument. The most recent // one had type `T`, and the earlier ones had types `Ts`. template class LogStreamer final { public: RTC_FORCE_INLINE LogStreamer(T arg, const LogStreamer* prior) : arg_(arg), prior_(prior) {} template ())), absl::enable_if_t::value || std::is_enum::value>* = nullptr> RTC_FORCE_INLINE LogStreamer operator<<(U arg) const { return LogStreamer(MakeVal(arg), this); } template ())), absl::enable_if_t::value && !std::is_enum::value>* = nullptr> RTC_FORCE_INLINE LogStreamer operator<<(const U& arg) const { return LogStreamer(MakeVal(arg), this); } #if RTC_CHECK_MSG_ENABLED template RTC_NORETURN RTC_FORCE_INLINE void Call(const char* file, const int line, const char* message, const Us&... args) const { prior_->Call(file, line, message, arg_, args...); } template RTC_NORETURN RTC_FORCE_INLINE void CallCheckOp(const char* file, const int line, const char* message, const Us&... args) const { prior_->CallCheckOp(file, line, message, arg_, args...); } #else template RTC_NORETURN RTC_FORCE_INLINE void Call(const char* file, const int line) const { prior_->Call(file, line); } #endif private: // The most recent argument. T arg_; // Earlier arguments. const LogStreamer* prior_; }; template class FatalLogCall final { public: FatalLogCall(const char* file, int line, const char* message) : file_(file), line_(line), message_(message) {} // This can be any binary operator with precedence lower than <<. template RTC_NORETURN RTC_FORCE_INLINE void operator&( const LogStreamer& streamer) { #if RTC_CHECK_MSG_ENABLED isCheckOp ? streamer.CallCheckOp(file_, line_, message_) : streamer.Call(file_, line_, message_); #else streamer.Call(file_, line_); #endif } private: const char* file_; int line_; const char* message_; }; #if RTC_DCHECK_IS_ON // Be helpful, and include file and line in the RTC_CHECK_NOTREACHED error // message. #define RTC_UNREACHABLE_FILE_AND_LINE_CALL_ARGS __FILE__, __LINE__ RTC_NORETURN RTC_EXPORT void UnreachableCodeReached(const char* file, int line); #else // Be mindful of binary size, and don't include file and line in the // RTC_CHECK_NOTREACHED error message. #define RTC_UNREACHABLE_FILE_AND_LINE_CALL_ARGS RTC_NORETURN RTC_EXPORT void UnreachableCodeReached(); #endif } // namespace webrtc_checks_impl // The actual stream used isn't important. We reference `ignored` in the code // but don't evaluate it; this is to avoid "unused variable" warnings (we do so // in a particularly convoluted way with an extra ?: because that appears to be // the simplest construct that keeps Visual Studio from complaining about // condition being unused). #define RTC_EAT_STREAM_PARAMETERS(ignored) \ (true ? true : ((void)(ignored), true)) \ ? static_cast(0) \ : ::rtc::webrtc_checks_impl::FatalLogCall("", 0, "") & \ ::rtc::webrtc_checks_impl::LogStreamer<>() // Call RTC_EAT_STREAM_PARAMETERS with an argument that fails to compile if // values of the same types as `a` and `b` can't be compared with the given // operation, and that would evaluate `a` and `b` if evaluated. #define RTC_EAT_STREAM_PARAMETERS_OP(op, a, b) \ RTC_EAT_STREAM_PARAMETERS(((void)::rtc::Safe##op(a, b))) // RTC_CHECK dies with a fatal error if condition is not true. It is *not* // controlled by NDEBUG or anything else, so the check will be executed // regardless of compilation mode. // // We make sure RTC_CHECK et al. always evaluates `condition`, as // doing RTC_CHECK(FunctionWithSideEffect()) is a common idiom. // // RTC_CHECK_OP is a helper macro for binary operators. // Don't use this macro directly in your code, use RTC_CHECK_EQ et al below. #if RTC_CHECK_MSG_ENABLED #define RTC_CHECK(condition) \ (condition) ? static_cast(0) \ : ::rtc::webrtc_checks_impl::FatalLogCall( \ __FILE__, __LINE__, #condition) & \ ::rtc::webrtc_checks_impl::LogStreamer<>() #define RTC_CHECK_OP(name, op, val1, val2) \ ::rtc::Safe##name((val1), (val2)) \ ? static_cast(0) \ : ::rtc::webrtc_checks_impl::FatalLogCall( \ __FILE__, __LINE__, #val1 " " #op " " #val2) & \ ::rtc::webrtc_checks_impl::LogStreamer<>() << (val1) << (val2) #else #define RTC_CHECK(condition) \ (condition) \ ? static_cast(0) \ : true ? ::rtc::webrtc_checks_impl::FatalLogCall(__FILE__, \ __LINE__, "") & \ ::rtc::webrtc_checks_impl::LogStreamer<>() \ : ::rtc::webrtc_checks_impl::FatalLogCall("", 0, "") & \ ::rtc::webrtc_checks_impl::LogStreamer<>() #define RTC_CHECK_OP(name, op, val1, val2) \ ::rtc::Safe##name((val1), (val2)) \ ? static_cast(0) \ : true ? ::rtc::webrtc_checks_impl::FatalLogCall(__FILE__, \ __LINE__, "") & \ ::rtc::webrtc_checks_impl::LogStreamer<>() \ : ::rtc::webrtc_checks_impl::FatalLogCall("", 0, "") & \ ::rtc::webrtc_checks_impl::LogStreamer<>() #endif #define RTC_CHECK_EQ(val1, val2) RTC_CHECK_OP(Eq, ==, val1, val2) #define RTC_CHECK_NE(val1, val2) RTC_CHECK_OP(Ne, !=, val1, val2) #define RTC_CHECK_LE(val1, val2) RTC_CHECK_OP(Le, <=, val1, val2) #define RTC_CHECK_LT(val1, val2) RTC_CHECK_OP(Lt, <, val1, val2) #define RTC_CHECK_GE(val1, val2) RTC_CHECK_OP(Ge, >=, val1, val2) #define RTC_CHECK_GT(val1, val2) RTC_CHECK_OP(Gt, >, val1, val2) // The RTC_DCHECK macro is equivalent to RTC_CHECK except that it only generates // code in debug builds. It does reference the condition parameter in all cases, // though, so callers won't risk getting warnings about unused variables. #if RTC_DCHECK_IS_ON #define RTC_DCHECK(condition) RTC_CHECK(condition) #define RTC_DCHECK_EQ(v1, v2) RTC_CHECK_EQ(v1, v2) #define RTC_DCHECK_NE(v1, v2) RTC_CHECK_NE(v1, v2) #define RTC_DCHECK_LE(v1, v2) RTC_CHECK_LE(v1, v2) #define RTC_DCHECK_LT(v1, v2) RTC_CHECK_LT(v1, v2) #define RTC_DCHECK_GE(v1, v2) RTC_CHECK_GE(v1, v2) #define RTC_DCHECK_GT(v1, v2) RTC_CHECK_GT(v1, v2) #else #define RTC_DCHECK(condition) RTC_EAT_STREAM_PARAMETERS(condition) #define RTC_DCHECK_EQ(v1, v2) RTC_EAT_STREAM_PARAMETERS_OP(Eq, v1, v2) #define RTC_DCHECK_NE(v1, v2) RTC_EAT_STREAM_PARAMETERS_OP(Ne, v1, v2) #define RTC_DCHECK_LE(v1, v2) RTC_EAT_STREAM_PARAMETERS_OP(Le, v1, v2) #define RTC_DCHECK_LT(v1, v2) RTC_EAT_STREAM_PARAMETERS_OP(Lt, v1, v2) #define RTC_DCHECK_GE(v1, v2) RTC_EAT_STREAM_PARAMETERS_OP(Ge, v1, v2) #define RTC_DCHECK_GT(v1, v2) RTC_EAT_STREAM_PARAMETERS_OP(Gt, v1, v2) #endif #define RTC_UNREACHABLE_CODE_HIT false #define RTC_DCHECK_NOTREACHED() RTC_DCHECK(RTC_UNREACHABLE_CODE_HIT) // Kills the process with an error message. Never returns. Use when you wish to // assert that a point in the code is never reached. #define RTC_CHECK_NOTREACHED() \ do { \ ::rtc::webrtc_checks_impl::UnreachableCodeReached( \ RTC_UNREACHABLE_FILE_AND_LINE_CALL_ARGS); \ } while (0) #define RTC_FATAL() \ ::rtc::webrtc_checks_impl::FatalLogCall(__FILE__, __LINE__, \ "FATAL()") & \ ::rtc::webrtc_checks_impl::LogStreamer<>() // Performs the integer division a/b and returns the result. CHECKs that the // remainder is zero. template inline T CheckedDivExact(T a, T b) { RTC_CHECK_EQ(a % b, 0) << a << " is not evenly divisible by " << b; return a / b; } } // namespace rtc #else // __cplusplus not defined // C version. Lacks many features compared to the C++ version, but usage // guidelines are the same. #define RTC_CHECK(condition) \ do { \ if (!(condition)) { \ rtc_FatalMessage(__FILE__, __LINE__, \ RTC_CHECK_EVAL_MESSAGE("CHECK failed: " #condition)); \ } \ } while (0) #define RTC_CHECK_EQ(a, b) RTC_CHECK((a) == (b)) #define RTC_CHECK_NE(a, b) RTC_CHECK((a) != (b)) #define RTC_CHECK_LE(a, b) RTC_CHECK((a) <= (b)) #define RTC_CHECK_LT(a, b) RTC_CHECK((a) < (b)) #define RTC_CHECK_GE(a, b) RTC_CHECK((a) >= (b)) #define RTC_CHECK_GT(a, b) RTC_CHECK((a) > (b)) #define RTC_DCHECK(condition) \ do { \ if (RTC_DCHECK_IS_ON && !(condition)) { \ rtc_FatalMessage(__FILE__, __LINE__, \ RTC_CHECK_EVAL_MESSAGE("DCHECK failed: " #condition)); \ } \ } while (0) #define RTC_DCHECK_EQ(a, b) RTC_DCHECK((a) == (b)) #define RTC_DCHECK_NE(a, b) RTC_DCHECK((a) != (b)) #define RTC_DCHECK_LE(a, b) RTC_DCHECK((a) <= (b)) #define RTC_DCHECK_LT(a, b) RTC_DCHECK((a) < (b)) #define RTC_DCHECK_GE(a, b) RTC_DCHECK((a) >= (b)) #define RTC_DCHECK_GT(a, b) RTC_DCHECK((a) > (b)) #endif // __cplusplus #endif // RTC_BASE_CHECKS_H_