// Copyright 2022 The Abseil Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // https://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // // ----------------------------------------------------------------------------- // File: log/internal/check_op.h // ----------------------------------------------------------------------------- // // This file declares helpers routines and macros used to implement `CHECK` // macros. #ifndef ABSL_LOG_INTERNAL_CHECK_OP_H_ #define ABSL_LOG_INTERNAL_CHECK_OP_H_ #include #include #include #include #include #include #include #include "absl/base/attributes.h" #include "absl/base/config.h" #include "absl/base/nullability.h" #include "absl/base/optimization.h" #include "absl/log/internal/nullguard.h" #include "absl/log/internal/nullstream.h" #include "absl/log/internal/strip.h" #include "absl/strings/has_absl_stringify.h" #include "absl/strings/string_view.h" // `ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL` wraps string literals that // should be stripped when `ABSL_MIN_LOG_LEVEL` exceeds `kFatal`. #ifdef ABSL_MIN_LOG_LEVEL #define ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL(literal) \ (::absl::LogSeverity::kFatal >= \ static_cast<::absl::LogSeverity>(ABSL_MIN_LOG_LEVEL) \ ? (literal) \ : "") #else #define ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL(literal) (literal) #endif #ifdef NDEBUG // `NDEBUG` is defined, so `DCHECK_EQ(x, y)` and so on do nothing. However, we // still want the compiler to parse `x` and `y`, because we don't want to lose // potentially useful errors and warnings. #define ABSL_LOG_INTERNAL_DCHECK_NOP(x, y) \ while (false && ((void)(x), (void)(y), 0)) \ ::absl::log_internal::NullStream().InternalStream() #endif #define ABSL_LOG_INTERNAL_CHECK_OP(name, op, val1, val1_text, val2, val2_text) \ while (::std::string* absl_log_internal_check_op_result \ ABSL_LOG_INTERNAL_ATTRIBUTE_UNUSED_IF_STRIP_LOG = \ ::absl::log_internal::name##Impl( \ ::absl::log_internal::GetReferenceableValue(val1), \ ::absl::log_internal::GetReferenceableValue(val2), \ ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL( \ val1_text " " #op " " val2_text))) \ ABSL_LOG_INTERNAL_CONDITION_FATAL(STATELESS, true) \ ABSL_LOG_INTERNAL_CHECK(*absl_log_internal_check_op_result).InternalStream() #define ABSL_LOG_INTERNAL_QCHECK_OP(name, op, val1, val1_text, val2, \ val2_text) \ while (::std::string* absl_log_internal_qcheck_op_result = \ ::absl::log_internal::name##Impl( \ ::absl::log_internal::GetReferenceableValue(val1), \ ::absl::log_internal::GetReferenceableValue(val2), \ ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL( \ val1_text " " #op " " val2_text))) \ ABSL_LOG_INTERNAL_CONDITION_QFATAL(STATELESS, true) \ ABSL_LOG_INTERNAL_QCHECK(*absl_log_internal_qcheck_op_result).InternalStream() #define ABSL_LOG_INTERNAL_CHECK_STROP(func, op, expected, s1, s1_text, s2, \ s2_text) \ while (::std::string* absl_log_internal_check_strop_result = \ ::absl::log_internal::Check##func##expected##Impl( \ (s1), (s2), \ ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL(s1_text " " #op \ " " s2_text))) \ ABSL_LOG_INTERNAL_CONDITION_FATAL(STATELESS, true) \ ABSL_LOG_INTERNAL_CHECK(*absl_log_internal_check_strop_result) \ .InternalStream() #define ABSL_LOG_INTERNAL_QCHECK_STROP(func, op, expected, s1, s1_text, s2, \ s2_text) \ while (::std::string* absl_log_internal_qcheck_strop_result = \ ::absl::log_internal::Check##func##expected##Impl( \ (s1), (s2), \ ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL(s1_text " " #op \ " " s2_text))) \ ABSL_LOG_INTERNAL_CONDITION_QFATAL(STATELESS, true) \ ABSL_LOG_INTERNAL_QCHECK(*absl_log_internal_qcheck_strop_result) \ .InternalStream() // This one is tricky: // * We must evaluate `val` exactly once, yet we need to do two things with it: // evaluate `.ok()` and (sometimes) `.ToString()`. // * `val` might be an `absl::Status` or some `absl::StatusOr`. // * `val` might be e.g. `ATemporary().GetStatus()`, which may return a // reference to a member of `ATemporary` that is only valid until the end of // the full expression. // * We don't want this file to depend on `absl::Status` `#include`s or linkage, // nor do we want to move the definition to status and introduce a dependency // in the other direction. We can be assured that callers must already have a // `Status` and the necessary `#include`s and linkage. // * Callsites should be small and fast (at least when `val.ok()`): one branch, // minimal stack footprint. // * In particular, the string concat stuff should be out-of-line and emitted // in only one TU to save linker input size // * We want the `val.ok()` check inline so static analyzers and optimizers can // see it. // * As usual, no braces so we can stream into the expansion with `operator<<`. // * Also as usual, it must expand to a single (partial) statement with no // ambiguous-else problems. // * When stripped by `ABSL_MIN_LOG_LEVEL`, we must discard the ` is OK` // string literal and abort without doing any streaming. We don't need to // strip the call to stringify the non-ok `Status` as long as we don't log it; // dropping the `Status`'s message text is out of scope. #define ABSL_LOG_INTERNAL_CHECK_OK(val, val_text) \ for (::std::pair \ absl_log_internal_check_ok_goo; \ absl_log_internal_check_ok_goo.first = \ ::absl::log_internal::AsStatus(val), \ absl_log_internal_check_ok_goo.second = \ ABSL_PREDICT_TRUE(absl_log_internal_check_ok_goo.first->ok()) \ ? nullptr \ : ::absl::status_internal::MakeCheckFailString( \ absl_log_internal_check_ok_goo.first, \ ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL(val_text \ " is OK")), \ !ABSL_PREDICT_TRUE(absl_log_internal_check_ok_goo.first->ok());) \ ABSL_LOG_INTERNAL_CONDITION_FATAL(STATELESS, true) \ ABSL_LOG_INTERNAL_CHECK(*absl_log_internal_check_ok_goo.second) \ .InternalStream() #define ABSL_LOG_INTERNAL_QCHECK_OK(val, val_text) \ for (::std::pair \ absl_log_internal_qcheck_ok_goo; \ absl_log_internal_qcheck_ok_goo.first = \ ::absl::log_internal::AsStatus(val), \ absl_log_internal_qcheck_ok_goo.second = \ ABSL_PREDICT_TRUE(absl_log_internal_qcheck_ok_goo.first->ok()) \ ? nullptr \ : ::absl::status_internal::MakeCheckFailString( \ absl_log_internal_qcheck_ok_goo.first, \ ABSL_LOG_INTERNAL_STRIP_STRING_LITERAL(val_text \ " is OK")), \ !ABSL_PREDICT_TRUE(absl_log_internal_qcheck_ok_goo.first->ok());) \ ABSL_LOG_INTERNAL_CONDITION_QFATAL(STATELESS, true) \ ABSL_LOG_INTERNAL_QCHECK(*absl_log_internal_qcheck_ok_goo.second) \ .InternalStream() namespace absl { ABSL_NAMESPACE_BEGIN class Status; template class StatusOr; namespace status_internal { ABSL_ATTRIBUTE_PURE_FUNCTION absl::Nonnull MakeCheckFailString( absl::Nonnull status, absl::Nonnull prefix); } // namespace status_internal namespace log_internal { // Convert a Status or a StatusOr to its underlying status value. // // (This implementation does not require a dep on absl::Status to work.) inline const absl::Status* AsStatus(const absl::Status& s) { return &s; } template const absl::Status* AsStatus(const absl::StatusOr& s) { return &s.status(); } // A helper class for formatting `expr (V1 vs. V2)` in a `CHECK_XX` statement. // See `MakeCheckOpString` for sample usage. class CheckOpMessageBuilder final { public: // Inserts `exprtext` and ` (` to the stream. explicit CheckOpMessageBuilder(const char* exprtext); ~CheckOpMessageBuilder() = default; // For inserting the first variable. std::ostream& ForVar1() { return stream_; } // For inserting the second variable (adds an intermediate ` vs. `). std::ostream& ForVar2(); // Get the result (inserts the closing `)`). std::string* NewString(); private: std::ostringstream stream_; }; // This formats a value for a failing `CHECK_XX` statement. Ordinarily, it uses // the definition for `operator<<`, with a few special cases below. template inline void MakeCheckOpValueString(std::ostream& os, const T& v) { os << log_internal::NullGuard::Guard(v); } // Overloads for char types provide readable values for unprintable characters. void MakeCheckOpValueString(std::ostream& os, char v); void MakeCheckOpValueString(std::ostream& os, signed char v); void MakeCheckOpValueString(std::ostream& os, unsigned char v); void MakeCheckOpValueString(std::ostream& os, const void* p); namespace detect_specialization { // MakeCheckOpString is being specialized for every T and U pair that is being // passed to the CHECK_op macros. However, there is a lot of redundancy in these // specializations that creates unnecessary library and binary bloat. // The number of instantiations tends to be O(n^2) because we have two // independent inputs. This technique works by reducing `n`. // // Most user-defined types being passed to CHECK_op end up being printed as a // builtin type. For example, enums tend to be implicitly converted to its // underlying type when calling operator<<, and pointers are printed with the // `const void*` overload. // To reduce the number of instantiations we coerce these values before calling // MakeCheckOpString instead of inside it. // // To detect if this coercion is needed, we duplicate all the relevant // operator<< overloads as specified in the standard, just in a different // namespace. If the call to `stream << value` becomes ambiguous, it means that // one of these overloads is the one selected by overload resolution. We then // do overload resolution again just with our overload set to see which one gets // selected. That tells us which type to coerce to. // If the augmented call was not ambiguous, it means that none of these were // selected and we can't coerce the input. // // As a secondary step to reduce code duplication, we promote integral types to // their 64-bit variant. This does not change the printed value, but reduces the // number of instantiations even further. Promoting an integer is very cheap at // the call site. int64_t operator<<(std::ostream&, short value); // NOLINT int64_t operator<<(std::ostream&, unsigned short value); // NOLINT int64_t operator<<(std::ostream&, int value); int64_t operator<<(std::ostream&, unsigned int value); int64_t operator<<(std::ostream&, long value); // NOLINT uint64_t operator<<(std::ostream&, unsigned long value); // NOLINT int64_t operator<<(std::ostream&, long long value); // NOLINT uint64_t operator<<(std::ostream&, unsigned long long value); // NOLINT float operator<<(std::ostream&, float value); double operator<<(std::ostream&, double value); long double operator<<(std::ostream&, long double value); bool operator<<(std::ostream&, bool value); const void* operator<<(std::ostream&, const void* value); const void* operator<<(std::ostream&, std::nullptr_t); // These `char` overloads are specified like this in the standard, so we have to // write them exactly the same to ensure the call is ambiguous. // If we wrote it in a different way (eg taking std::ostream instead of the // template) then one call might have a higher rank than the other and it would // not be ambiguous. template char operator<<(std::basic_ostream&, char); template signed char operator<<(std::basic_ostream&, signed char); template unsigned char operator<<(std::basic_ostream&, unsigned char); template const char* operator<<(std::basic_ostream&, const char*); template const signed char* operator<<(std::basic_ostream&, const signed char*); template const unsigned char* operator<<(std::basic_ostream&, const unsigned char*); // This overload triggers when the call is not ambiguous. // It means that T is being printed with some overload not on this list. // We keep the value as `const T&`. template () << std::declval())> const T& Detect(int); // This overload triggers when the call is ambiguous. // It means that T is either one from this list or printed as one from this // list. Eg an enum that decays to `int` for printing. // We ask the overload set to give us the type we want to convert it to. template decltype(detect_specialization::operator<<(std::declval(), std::declval())) Detect(char); // A sink for AbslStringify which redirects everything to a std::ostream. class StringifySink { public: explicit StringifySink(std::ostream& os ABSL_ATTRIBUTE_LIFETIME_BOUND); void Append(absl::string_view text); void Append(size_t length, char ch); friend void AbslFormatFlush(StringifySink* sink, absl::string_view text); private: std::ostream& os_; }; // Wraps a type implementing AbslStringify, and implements operator<<. template class StringifyToStreamWrapper { public: explicit StringifyToStreamWrapper(const T& v ABSL_ATTRIBUTE_LIFETIME_BOUND) : v_(v) {} friend std::ostream& operator<<(std::ostream& os, const StringifyToStreamWrapper& wrapper) { StringifySink sink(os); AbslStringify(sink, wrapper.v_); return os; } private: const T& v_; }; // This overload triggers when T implements AbslStringify. // StringifyToStreamWrapper is used to allow MakeCheckOpString to use // operator<<. template std::enable_if_t::value, StringifyToStreamWrapper> Detect(...); // Ellipsis has lowest preference when int passed. } // namespace detect_specialization template using CheckOpStreamType = decltype(detect_specialization::Detect(0)); // Build the error message string. Specify no inlining for code size. template ABSL_ATTRIBUTE_RETURNS_NONNULL std::string* MakeCheckOpString( T1 v1, T2 v2, const char* exprtext) ABSL_ATTRIBUTE_NOINLINE; template std::string* MakeCheckOpString(T1 v1, T2 v2, const char* exprtext) { CheckOpMessageBuilder comb(exprtext); MakeCheckOpValueString(comb.ForVar1(), v1); MakeCheckOpValueString(comb.ForVar2(), v2); return comb.NewString(); } // Add a few commonly used instantiations as extern to reduce size of objects // files. #define ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(x) \ extern template std::string* MakeCheckOpString(x, x, const char*) ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(bool); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(int64_t); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(uint64_t); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(float); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(double); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(char); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(unsigned char); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(const std::string&); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(const absl::string_view&); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(const char*); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(const signed char*); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(const unsigned char*); ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN(const void*); #undef ABSL_LOG_INTERNAL_DEFINE_MAKE_CHECK_OP_STRING_EXTERN // `ABSL_LOG_INTERNAL_CHECK_OP_IMPL_RESULT` skips formatting the Check_OP result // string iff `ABSL_MIN_LOG_LEVEL` exceeds `kFatal`, instead returning an empty // string. #ifdef ABSL_MIN_LOG_LEVEL #define ABSL_LOG_INTERNAL_CHECK_OP_IMPL_RESULT(U1, U2, v1, v2, exprtext) \ ((::absl::LogSeverity::kFatal >= \ static_cast<::absl::LogSeverity>(ABSL_MIN_LOG_LEVEL)) \ ? MakeCheckOpString(v1, v2, exprtext) \ : new std::string()) #else #define ABSL_LOG_INTERNAL_CHECK_OP_IMPL_RESULT(U1, U2, v1, v2, exprtext) \ MakeCheckOpString(v1, v2, exprtext) #endif // Helper functions for `ABSL_LOG_INTERNAL_CHECK_OP` macro family. The // `(int, int)` override works around the issue that the compiler will not // instantiate the template version of the function on values of unnamed enum // type. #define ABSL_LOG_INTERNAL_CHECK_OP_IMPL(name, op) \ template \ inline constexpr ::std::string* name##Impl(const T1& v1, const T2& v2, \ const char* exprtext) { \ using U1 = CheckOpStreamType; \ using U2 = CheckOpStreamType; \ return ABSL_PREDICT_TRUE(v1 op v2) \ ? nullptr \ : ABSL_LOG_INTERNAL_CHECK_OP_IMPL_RESULT(U1, U2, U1(v1), \ U2(v2), exprtext); \ } \ inline constexpr ::std::string* name##Impl(int v1, int v2, \ const char* exprtext) { \ return name##Impl(v1, v2, exprtext); \ } ABSL_LOG_INTERNAL_CHECK_OP_IMPL(Check_EQ, ==) ABSL_LOG_INTERNAL_CHECK_OP_IMPL(Check_NE, !=) ABSL_LOG_INTERNAL_CHECK_OP_IMPL(Check_LE, <=) ABSL_LOG_INTERNAL_CHECK_OP_IMPL(Check_LT, <) ABSL_LOG_INTERNAL_CHECK_OP_IMPL(Check_GE, >=) ABSL_LOG_INTERNAL_CHECK_OP_IMPL(Check_GT, >) #undef ABSL_LOG_INTERNAL_CHECK_OP_IMPL_RESULT #undef ABSL_LOG_INTERNAL_CHECK_OP_IMPL std::string* CheckstrcmptrueImpl(const char* s1, const char* s2, const char* exprtext); std::string* CheckstrcmpfalseImpl(const char* s1, const char* s2, const char* exprtext); std::string* CheckstrcasecmptrueImpl(const char* s1, const char* s2, const char* exprtext); std::string* CheckstrcasecmpfalseImpl(const char* s1, const char* s2, const char* exprtext); // `CHECK_EQ` and friends want to pass their arguments by reference, however // this winds up exposing lots of cases where people have defined and // initialized static const data members but never declared them (i.e. in a .cc // file), meaning they are not referenceable. This function avoids that problem // for integers (the most common cases) by overloading for every primitive // integer type, even the ones we discourage, and returning them by value. template inline constexpr const T& GetReferenceableValue(const T& t) { return t; } inline constexpr char GetReferenceableValue(char t) { return t; } inline constexpr unsigned char GetReferenceableValue(unsigned char t) { return t; } inline constexpr signed char GetReferenceableValue(signed char t) { return t; } inline constexpr short GetReferenceableValue(short t) { return t; } // NOLINT inline constexpr unsigned short GetReferenceableValue( // NOLINT unsigned short t) { // NOLINT return t; } inline constexpr int GetReferenceableValue(int t) { return t; } inline constexpr unsigned int GetReferenceableValue(unsigned int t) { return t; } inline constexpr long GetReferenceableValue(long t) { return t; } // NOLINT inline constexpr unsigned long GetReferenceableValue( // NOLINT unsigned long t) { // NOLINT return t; } inline constexpr long long GetReferenceableValue(long long t) { // NOLINT return t; } inline constexpr unsigned long long GetReferenceableValue( // NOLINT unsigned long long t) { // NOLINT return t; } } // namespace log_internal ABSL_NAMESPACE_END } // namespace absl #endif // ABSL_LOG_INTERNAL_CHECK_OP_H_