absl/log/internal/log_message.h - third_party/github/abseil/abseil-cpp - Git at Google

 // 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/log_message.h
 // -----------------------------------------------------------------------------
 //
 // This file declares `class absl::log_internal::LogMessage`. This class more or
 // less represents a particular log message. LOG/CHECK macros create a
 // temporary instance of `LogMessage` and then stream values to it.  At the end
 // of the LOG/CHECK statement, LogMessage instance goes out of scope and
 // `~LogMessage` directs the message to the registered log sinks.
 // Heap-allocation of `LogMessage` is unsupported.  Construction outside of a
 // `LOG` macro is unsupported.

 #ifndef ABSL_LOG_INTERNAL_LOG_MESSAGE_H_
 #define ABSL_LOG_INTERNAL_LOG_MESSAGE_H_

 #include <cstddef>
 #include <ios>
 #include <memory>
 #include <ostream>
 #include <streambuf>
 #include <string>
 #include <type_traits>

 #include "absl/base/attributes.h"
 #include "absl/base/config.h"
 #include "absl/base/internal/errno_saver.h"
 #include "absl/base/log_severity.h"
 #include "absl/base/nullability.h"
 #include "absl/log/internal/nullguard.h"
 #include "absl/log/log_entry.h"
 #include "absl/log/log_sink.h"
 #include "absl/strings/has_absl_stringify.h"
 #include "absl/strings/string_view.h"
 #include "absl/time/time.h"

 namespace absl {
 ABSL_NAMESPACE_BEGIN
 namespace log_internal {
 constexpr int kLogMessageBufferSize = 15000;

 class LogMessage {
  public:
   struct InfoTag {};
   struct WarningTag {};
   struct ErrorTag {};

   // Used for `LOG`.
   LogMessage(absl::Nonnull<const char*> file, int line,
              absl::LogSeverity severity) ABSL_ATTRIBUTE_COLD;
   // These constructors are slightly smaller/faster to call; the severity is
   // curried into the function pointer.
   LogMessage(absl::Nonnull<const char*> file, int line,
              InfoTag) ABSL_ATTRIBUTE_COLD ABSL_ATTRIBUTE_NOINLINE;
   LogMessage(absl::Nonnull<const char*> file, int line,
              WarningTag) ABSL_ATTRIBUTE_COLD ABSL_ATTRIBUTE_NOINLINE;
   LogMessage(absl::Nonnull<const char*> file, int line,
              ErrorTag) ABSL_ATTRIBUTE_COLD ABSL_ATTRIBUTE_NOINLINE;
   LogMessage(const LogMessage&) = delete;
   LogMessage& operator=(const LogMessage&) = delete;
   ~LogMessage() ABSL_ATTRIBUTE_COLD;

   // Overrides the location inferred from the callsite.  The string pointed to
   // by `file` must be valid until the end of the statement.
   LogMessage& AtLocation(absl::string_view file, int line);
   // Omits the prefix from this line.  The prefix includes metadata about the
   // logged data such as source code location and timestamp.
   LogMessage& NoPrefix();
   // Sets the verbosity field of the logged message as if it was logged by
   // `VLOG(verbose_level)`.  Unlike `VLOG`, this method does not affect
   // evaluation of the statement when the specified `verbose_level` has been
   // disabled.  The only effect is on `absl::LogSink` implementations which
   // make use of the `absl::LogSink::verbosity()` value.  The value
   // `absl::LogEntry::kNoVerbosityLevel` can be specified to mark the message
   // not verbose.
   LogMessage& WithVerbosity(int verbose_level);
   // Uses the specified timestamp instead of one collected in the constructor.
   LogMessage& WithTimestamp(absl::Time timestamp);
   // Uses the specified thread ID instead of one collected in the constructor.
   LogMessage& WithThreadID(absl::LogEntry::tid_t tid);
   // Copies all metadata (but no data) from the specified `absl::LogEntry`.
   LogMessage& WithMetadataFrom(const absl::LogEntry& entry);
   // Appends to the logged message a colon, a space, a textual description of
   // the current value of `errno` (as by strerror(3)), and the numerical value
   // of `errno`.
   LogMessage& WithPerror();
   // Sends this message to `*sink` in addition to whatever other sinks it would
   // otherwise have been sent to.
   LogMessage& ToSinkAlso(absl::Nonnull<absl::LogSink*> sink);
   // Sends this message to `*sink` and no others.
   LogMessage& ToSinkOnly(absl::Nonnull<absl::LogSink*> sink);

   // Don't call this method from outside this library.
   LogMessage& InternalStream() { return *this; }

   // By-value overloads for small, common types let us overlook common failures
   // to define globals and static data members (i.e. in a .cc file).
   // NOLINTBEGIN(runtime/int)
   // NOLINTBEGIN(google-runtime-int)
   // clang-format off:  The CUDA toolchain cannot handle these <<<'s
   LogMessage& operator<<(char v) { return operator<< <char>(v); }
   LogMessage& operator<<(signed char v) { return operator<< <signed char>(v); }
   LogMessage& operator<<(unsigned char v) {
     return operator<< <unsigned char>(v);
   }
   LogMessage& operator<<(signed short v) {
     return operator<< <signed short>(v);
   }
   LogMessage& operator<<(signed int v) { return operator<< <signed int>(v); }
   LogMessage& operator<<(signed long v) {
     return operator<< <signed long>(v);
   }
   LogMessage& operator<<(signed long long v) {
     return operator<< <signed long long>(v);
   }
   LogMessage& operator<<(unsigned short v) {
     return operator<< <unsigned short>(v);
   }
   LogMessage& operator<<(unsigned int v) {
     return operator<< <unsigned int>(v);
   }
   LogMessage& operator<<(unsigned long v) {
     return operator<< <unsigned long>(v);
   }
   LogMessage& operator<<(unsigned long long v) {
     return operator<< <unsigned long long>(v);
   }
   LogMessage& operator<<(absl::Nullable<void*> v) {
     return operator<< <void*>(v);
   }
   LogMessage& operator<<(absl::Nullable<const void*> v) {
     return operator<< <const void*>(v);
   }
   LogMessage& operator<<(float v) { return operator<< <float>(v); }
   LogMessage& operator<<(double v) { return operator<< <double>(v); }
   LogMessage& operator<<(bool v) { return operator<< <bool>(v); }
   // clang-format on
   // NOLINTEND(google-runtime-int)
   // NOLINTEND(runtime/int)

   // These overloads are more efficient since no `ostream` is involved.
   LogMessage& operator<<(const std::string& v);
   LogMessage& operator<<(absl::string_view v);

   // Handle stream manipulators e.g. std::endl.
   LogMessage& operator<<(absl::Nonnull<std::ostream& (*)(std::ostream & os)> m);
   LogMessage& operator<<(
       absl::Nonnull<std::ios_base& (*)(std::ios_base & os)> m);

   // Literal strings.  This allows us to record C string literals as literals in
   // the logging.proto.Value.
   //
   // Allow this overload to be inlined to prevent generating instantiations of
   // this template for every value of `SIZE` encountered in each source code
   // file. That significantly increases linker input sizes. Inlining is cheap
   // because the argument to this overload is almost always a string literal so
   // the call to `strlen` can be replaced at compile time. The overload for
   // `char[]` below should not be inlined. The compiler typically does not have
   // the string at compile time and cannot replace the call to `strlen` so
   // inlining it increases the binary size. See the discussion on
   // cl/107527369.
   template <int SIZE>
   LogMessage& operator<<(const char (&buf)[SIZE]);

   // This prevents non-const `char[]` arrays from looking like literals.
   template <int SIZE>
   LogMessage& operator<<(char (&buf)[SIZE]) ABSL_ATTRIBUTE_NOINLINE;

   // Types that support `AbslStringify()` are serialized that way.
   template <typename T,
             typename std::enable_if<absl::HasAbslStringify<T>::value,
                                     int>::type = 0>
   LogMessage& operator<<(const T& v) ABSL_ATTRIBUTE_NOINLINE;

   // Types that don't support `AbslStringify()` but do support streaming into a
   // `std::ostream&` are serialized that way.
   template <typename T,
             typename std::enable_if<!absl::HasAbslStringify<T>::value,
                                     int>::type = 0>
   LogMessage& operator<<(const T& v) ABSL_ATTRIBUTE_NOINLINE;

   // Note: We explicitly do not support `operator<<` for non-const references
   // because it breaks logging of non-integer bitfield types (i.e., enums).

  protected:
   // Call `abort()` or similar to perform `LOG(FATAL)` crash.  It is assumed
   // that the caller has already generated and written the trace as appropriate.
   [[noreturn]] static void FailWithoutStackTrace();

   // Similar to `FailWithoutStackTrace()`, but without `abort()`.  Terminates
   // the process with an error exit code.
   [[noreturn]] static void FailQuietly();

   // Dispatches the completed `absl::LogEntry` to applicable `absl::LogSink`s.
   // This might as well be inlined into `~LogMessage` except that
   // `~LogMessageFatal` needs to call it early.
   void Flush();

   // After this is called, failures are done as quiet as possible for this log
   // message.
   void SetFailQuietly();

  private:
   struct LogMessageData;  // Opaque type containing message state
   friend class AsLiteralImpl;
   friend class StringifySink;

   // This streambuf writes directly into the structured logging buffer so that
   // arbitrary types can be encoded as string data (using
   // `operator<<(std::ostream &, ...)` without any extra allocation or copying.
   // Space is reserved before the data to store the length field, which is
   // filled in by `~OstreamView`.
   class OstreamView final : public std::streambuf {
    public:
     explicit OstreamView(LogMessageData& message_data);
     ~OstreamView() override;
     OstreamView(const OstreamView&) = delete;
     OstreamView& operator=(const OstreamView&) = delete;
     std::ostream& stream();

    private:
     LogMessageData& data_;
     absl::Span<char> encoded_remaining_copy_;
     absl::Span<char> message_start_;
     absl::Span<char> string_start_;
   };

   enum class StringType {
     kLiteral,
     kNotLiteral,
   };
   template <StringType str_type>
   void CopyToEncodedBuffer(absl::string_view str) ABSL_ATTRIBUTE_NOINLINE;
   template <StringType str_type>
   void CopyToEncodedBuffer(char ch, size_t num) ABSL_ATTRIBUTE_NOINLINE;

   // Returns `true` if the message is fatal or enabled debug-fatal.
   bool IsFatal() const;

   // Records some tombstone-type data in anticipation of `Die`.
   void PrepareToDie();
   void Die();

   void SendToLog();

   // Checks `FLAGS_log_backtrace_at` and appends a backtrace if appropriate.
   void LogBacktraceIfNeeded();

   // This should be the first data member so that its initializer captures errno
   // before any other initializers alter it (e.g. with calls to new) and so that
   // no other destructors run afterward an alter it (e.g. with calls to delete).
   absl::base_internal::ErrnoSaver errno_saver_;

   // We keep the data in a separate struct so that each instance of `LogMessage`
   // uses less stack space.
   absl::Nonnull<std::unique_ptr<LogMessageData>> data_;
 };

 // Helper class so that `AbslStringify()` can modify the LogMessage.
 class StringifySink final {
  public:
   explicit StringifySink(LogMessage& message) : message_(message) {}

   void Append(size_t count, char ch) {
     message_.CopyToEncodedBuffer<LogMessage::StringType::kNotLiteral>(ch,
                                                                       count);
   }

   void Append(absl::string_view v) {
     message_.CopyToEncodedBuffer<LogMessage::StringType::kNotLiteral>(v);
   }

   // For types that implement `AbslStringify` using `absl::Format()`.
   friend void AbslFormatFlush(absl::Nonnull<StringifySink*> sink,
                               absl::string_view v) {
     sink->Append(v);
   }

  private:
   LogMessage& message_;
 };

 // Note: the following is declared `ABSL_ATTRIBUTE_NOINLINE`
 template <typename T,
           typename std::enable_if<absl::HasAbslStringify<T>::value, int>::type>
 LogMessage& LogMessage::operator<<(const T& v) {
   StringifySink sink(*this);
   // Replace with public API.
   AbslStringify(sink, v);
   return *this;
 }

 // Note: the following is declared `ABSL_ATTRIBUTE_NOINLINE`
 template <typename T,
           typename std::enable_if<!absl::HasAbslStringify<T>::value, int>::type>
 LogMessage& LogMessage::operator<<(const T& v) {
   OstreamView view(*data_);
   view.stream() << log_internal::NullGuard<T>().Guard(v);
   return *this;
 }

 template <int SIZE>
 LogMessage& LogMessage::operator<<(const char (&buf)[SIZE]) {
   CopyToEncodedBuffer<StringType::kLiteral>(buf);
   return *this;
 }

 // Note: the following is declared `ABSL_ATTRIBUTE_NOINLINE`
 template <int SIZE>
 LogMessage& LogMessage::operator<<(char (&buf)[SIZE]) {
   CopyToEncodedBuffer<StringType::kNotLiteral>(buf);
   return *this;
 }
 // We instantiate these specializations in the library's TU to save space in
 // other TUs.  Since the template is marked `ABSL_ATTRIBUTE_NOINLINE` we will be
 // emitting a function call either way.
 // NOLINTBEGIN(runtime/int)
 // NOLINTBEGIN(google-runtime-int)
 extern template LogMessage& LogMessage::operator<<(const char& v);
 extern template LogMessage& LogMessage::operator<<(const signed char& v);
 extern template LogMessage& LogMessage::operator<<(const unsigned char& v);
 extern template LogMessage& LogMessage::operator<<(const short& v);
 extern template LogMessage& LogMessage::operator<<(const unsigned short& v);
 extern template LogMessage& LogMessage::operator<<(const int& v);
 extern template LogMessage& LogMessage::operator<<(const unsigned int& v);
 extern template LogMessage& LogMessage::operator<<(const long& v);
 extern template LogMessage& LogMessage::operator<<(const unsigned long& v);
 extern template LogMessage& LogMessage::operator<<(const long long& v);
 extern template LogMessage& LogMessage::operator<<(const unsigned long long& v);
 extern template LogMessage& LogMessage::operator<<(
     absl::Nullable<void*> const& v);
 extern template LogMessage& LogMessage::operator<<(
     absl::Nullable<const void*> const& v);
 extern template LogMessage& LogMessage::operator<<(const float& v);
 extern template LogMessage& LogMessage::operator<<(const double& v);
 extern template LogMessage& LogMessage::operator<<(const bool& v);
 // NOLINTEND(google-runtime-int)
 // NOLINTEND(runtime/int)

 extern template void LogMessage::CopyToEncodedBuffer<
     LogMessage::StringType::kLiteral>(absl::string_view str);
 extern template void LogMessage::CopyToEncodedBuffer<
     LogMessage::StringType::kNotLiteral>(absl::string_view str);
 extern template void
 LogMessage::CopyToEncodedBuffer<LogMessage::StringType::kLiteral>(char ch,
                                                                   size_t num);
 extern template void LogMessage::CopyToEncodedBuffer<
     LogMessage::StringType::kNotLiteral>(char ch, size_t num);

 // `LogMessageFatal` ensures the process will exit in failure after logging this
 // message.
 class LogMessageFatal final : public LogMessage {
  public:
   LogMessageFatal(absl::Nonnull<const char*> file,
                   int line) ABSL_ATTRIBUTE_COLD;
   LogMessageFatal(absl::Nonnull<const char*> file, int line,
                   absl::string_view failure_msg) ABSL_ATTRIBUTE_COLD;
   [[noreturn]] ~LogMessageFatal();
 };

 // `LogMessageDebugFatal` ensures the process will exit in failure after logging
 // this message. It matches LogMessageFatal but is not [[noreturn]] as it's used
 // for DLOG(FATAL) variants.
 class LogMessageDebugFatal final : public LogMessage {
  public:
   LogMessageDebugFatal(absl::Nonnull<const char*> file,
                        int line) ABSL_ATTRIBUTE_COLD;
   ~LogMessageDebugFatal();
 };

 class LogMessageQuietlyDebugFatal final : public LogMessage {
  public:
   // DLOG(QFATAL) calls this instead of LogMessageQuietlyFatal to make sure the
   // destructor is not [[noreturn]] even if this is always FATAL as this is only
   // invoked when DLOG() is enabled.
   LogMessageQuietlyDebugFatal(absl::Nonnull<const char*> file,
                               int line) ABSL_ATTRIBUTE_COLD;
   ~LogMessageQuietlyDebugFatal();
 };

 // Used for LOG(QFATAL) to make sure it's properly understood as [[noreturn]].
 class LogMessageQuietlyFatal final : public LogMessage {
  public:
   LogMessageQuietlyFatal(absl::Nonnull<const char*> file,
                          int line) ABSL_ATTRIBUTE_COLD;
   LogMessageQuietlyFatal(absl::Nonnull<const char*> file, int line,
                          absl::string_view failure_msg) ABSL_ATTRIBUTE_COLD;
   [[noreturn]] ~LogMessageQuietlyFatal();
 };

 }  // namespace log_internal
 ABSL_NAMESPACE_END
 }  // namespace absl

 extern "C" ABSL_ATTRIBUTE_WEAK void ABSL_INTERNAL_C_SYMBOL(
     AbslInternalOnFatalLogMessage)(const absl::LogEntry&);

 #endif  // ABSL_LOG_INTERNAL_LOG_MESSAGE_H_
	// 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/log_message.h
	// -----------------------------------------------------------------------------
	//
	// This file declares `class absl::log_internal::LogMessage`. This class more or
	// less represents a particular log message. LOG/CHECK macros create a
	// temporary instance of `LogMessage` and then stream values to it. At the end
	// of the LOG/CHECK statement, LogMessage instance goes out of scope and
	// `~LogMessage` directs the message to the registered log sinks.
	// Heap-allocation of `LogMessage` is unsupported. Construction outside of a
	// `LOG` macro is unsupported.

	#ifndef ABSL_LOG_INTERNAL_LOG_MESSAGE_H_
	#define ABSL_LOG_INTERNAL_LOG_MESSAGE_H_

	#include <cstddef>
	#include <ios>
	#include <memory>
	#include <ostream>
	#include <streambuf>
	#include <string>
	#include <type_traits>

	#include "absl/base/attributes.h"
	#include "absl/base/config.h"
	#include "absl/base/internal/errno_saver.h"
	#include "absl/base/log_severity.h"
	#include "absl/base/nullability.h"
	#include "absl/log/internal/nullguard.h"
	#include "absl/log/log_entry.h"
	#include "absl/log/log_sink.h"
	#include "absl/strings/has_absl_stringify.h"
	#include "absl/strings/string_view.h"
	#include "absl/time/time.h"

	namespace absl {
	ABSL_NAMESPACE_BEGIN
	namespace log_internal {
	constexpr int kLogMessageBufferSize = 15000;

	class LogMessage {
	public:
	struct InfoTag {};
	struct WarningTag {};
	struct ErrorTag {};

	// Used for `LOG`.
	LogMessage(absl::Nonnull<const char*> file, int line,
	absl::LogSeverity severity) ABSL_ATTRIBUTE_COLD;
	// These constructors are slightly smaller/faster to call; the severity is
	// curried into the function pointer.
	LogMessage(absl::Nonnull<const char*> file, int line,
	InfoTag) ABSL_ATTRIBUTE_COLD ABSL_ATTRIBUTE_NOINLINE;
	LogMessage(absl::Nonnull<const char*> file, int line,
	WarningTag) ABSL_ATTRIBUTE_COLD ABSL_ATTRIBUTE_NOINLINE;
	LogMessage(absl::Nonnull<const char*> file, int line,
	ErrorTag) ABSL_ATTRIBUTE_COLD ABSL_ATTRIBUTE_NOINLINE;
	LogMessage(const LogMessage&) = delete;
	LogMessage& operator=(const LogMessage&) = delete;
	~LogMessage() ABSL_ATTRIBUTE_COLD;

	// Overrides the location inferred from the callsite. The string pointed to
	// by `file` must be valid until the end of the statement.
	LogMessage& AtLocation(absl::string_view file, int line);
	// Omits the prefix from this line. The prefix includes metadata about the
	// logged data such as source code location and timestamp.
	LogMessage& NoPrefix();
	// Sets the verbosity field of the logged message as if it was logged by
	// `VLOG(verbose_level)`. Unlike `VLOG`, this method does not affect
	// evaluation of the statement when the specified `verbose_level` has been
	// disabled. The only effect is on `absl::LogSink` implementations which
	// make use of the `absl::LogSink::verbosity()` value. The value
	// `absl::LogEntry::kNoVerbosityLevel` can be specified to mark the message
	// not verbose.
	LogMessage& WithVerbosity(int verbose_level);
	// Uses the specified timestamp instead of one collected in the constructor.
	LogMessage& WithTimestamp(absl::Time timestamp);
	// Uses the specified thread ID instead of one collected in the constructor.
	LogMessage& WithThreadID(absl::LogEntry::tid_t tid);
	// Copies all metadata (but no data) from the specified `absl::LogEntry`.
	LogMessage& WithMetadataFrom(const absl::LogEntry& entry);
	// Appends to the logged message a colon, a space, a textual description of
	// the current value of `errno` (as by strerror(3)), and the numerical value
	// of `errno`.
	LogMessage& WithPerror();
	// Sends this message to `*sink` in addition to whatever other sinks it would
	// otherwise have been sent to.
	LogMessage& ToSinkAlso(absl::Nonnull<absl::LogSink*> sink);
	// Sends this message to `*sink` and no others.
	LogMessage& ToSinkOnly(absl::Nonnull<absl::LogSink*> sink);

	// Don't call this method from outside this library.
	LogMessage& InternalStream() { return *this; }

	// By-value overloads for small, common types let us overlook common failures
	// to define globals and static data members (i.e. in a .cc file).
	// NOLINTBEGIN(runtime/int)
	// NOLINTBEGIN(google-runtime-int)
	// clang-format off: The CUDA toolchain cannot handle these <<<'s
	LogMessage& operator<<(char v) { return operator<< <char>(v); }
	LogMessage& operator<<(signed char v) { return operator<< <signed char>(v); }
	LogMessage& operator<<(unsigned char v) {
	return operator<< <unsigned char>(v);
	}
	LogMessage& operator<<(signed short v) {
	return operator<< <signed short>(v);
	}
	LogMessage& operator<<(signed int v) { return operator<< <signed int>(v); }
	LogMessage& operator<<(signed long v) {
	return operator<< <signed long>(v);
	}
	LogMessage& operator<<(signed long long v) {
	return operator<< <signed long long>(v);
	}
	LogMessage& operator<<(unsigned short v) {
	return operator<< <unsigned short>(v);
	}
	LogMessage& operator<<(unsigned int v) {
	return operator<< <unsigned int>(v);
	}
	LogMessage& operator<<(unsigned long v) {
	return operator<< <unsigned long>(v);
	}
	LogMessage& operator<<(unsigned long long v) {
	return operator<< <unsigned long long>(v);
	}
	LogMessage& operator<<(absl::Nullable<void*> v) {
	return operator<< <void*>(v);
	}
	LogMessage& operator<<(absl::Nullable<const void*> v) {
	return operator<< <const void*>(v);
	}
	LogMessage& operator<<(float v) { return operator<< <float>(v); }
	LogMessage& operator<<(double v) { return operator<< <double>(v); }
	LogMessage& operator<<(bool v) { return operator<< <bool>(v); }
	// clang-format on
	// NOLINTEND(google-runtime-int)
	// NOLINTEND(runtime/int)

	// These overloads are more efficient since no `ostream` is involved.
	LogMessage& operator<<(const std::string& v);
	LogMessage& operator<<(absl::string_view v);

	// Handle stream manipulators e.g. std::endl.
	LogMessage& operator<<(absl::Nonnull<std::ostream& (*)(std::ostream & os)> m);
	LogMessage& operator<<(
	absl::Nonnull<std::ios_base& (*)(std::ios_base & os)> m);

	// Literal strings. This allows us to record C string literals as literals in
	// the logging.proto.Value.
	//
	// Allow this overload to be inlined to prevent generating instantiations of
	// this template for every value of `SIZE` encountered in each source code
	// file. That significantly increases linker input sizes. Inlining is cheap
	// because the argument to this overload is almost always a string literal so
	// the call to `strlen` can be replaced at compile time. The overload for
	// `char[]` below should not be inlined. The compiler typically does not have
	// the string at compile time and cannot replace the call to `strlen` so
	// inlining it increases the binary size. See the discussion on
	// cl/107527369.
	template <int SIZE>
	LogMessage& operator<<(const char (&buf)[SIZE]);

	// This prevents non-const `char[]` arrays from looking like literals.
	template <int SIZE>
	LogMessage& operator<<(char (&buf)[SIZE]) ABSL_ATTRIBUTE_NOINLINE;

	// Types that support `AbslStringify()` are serialized that way.
	template <typename T,
	typename std::enable_if<absl::HasAbslStringify<T>::value,
	int>::type = 0>
	LogMessage& operator<<(const T& v) ABSL_ATTRIBUTE_NOINLINE;

	// Types that don't support `AbslStringify()` but do support streaming into a
	// `std::ostream&` are serialized that way.
	template <typename T,
	typename std::enable_if<!absl::HasAbslStringify<T>::value,
	int>::type = 0>
	LogMessage& operator<<(const T& v) ABSL_ATTRIBUTE_NOINLINE;

	// Note: We explicitly do not support `operator<<` for non-const references
	// because it breaks logging of non-integer bitfield types (i.e., enums).

	protected:
	// Call `abort()` or similar to perform `LOG(FATAL)` crash. It is assumed
	// that the caller has already generated and written the trace as appropriate.
	[[noreturn]] static void FailWithoutStackTrace();

	// Similar to `FailWithoutStackTrace()`, but without `abort()`. Terminates
	// the process with an error exit code.
	[[noreturn]] static void FailQuietly();

	// Dispatches the completed `absl::LogEntry` to applicable `absl::LogSink`s.
	// This might as well be inlined into `~LogMessage` except that
	// `~LogMessageFatal` needs to call it early.
	void Flush();

	// After this is called, failures are done as quiet as possible for this log
	// message.
	void SetFailQuietly();

	private:
	struct LogMessageData; // Opaque type containing message state
	friend class AsLiteralImpl;
	friend class StringifySink;

	// This streambuf writes directly into the structured logging buffer so that
	// arbitrary types can be encoded as string data (using
	// `operator<<(std::ostream &, ...)` without any extra allocation or copying.
	// Space is reserved before the data to store the length field, which is
	// filled in by `~OstreamView`.
	class OstreamView final : public std::streambuf {
	public:
	explicit OstreamView(LogMessageData& message_data);
	~OstreamView() override;
	OstreamView(const OstreamView&) = delete;
	OstreamView& operator=(const OstreamView&) = delete;
	std::ostream& stream();

	private:
	LogMessageData& data_;
	absl::Span<char> encoded_remaining_copy_;
	absl::Span<char> message_start_;
	absl::Span<char> string_start_;
	};

	enum class StringType {
	kLiteral,
	kNotLiteral,
	};
	template <StringType str_type>
	void CopyToEncodedBuffer(absl::string_view str) ABSL_ATTRIBUTE_NOINLINE;
	template <StringType str_type>
	void CopyToEncodedBuffer(char ch, size_t num) ABSL_ATTRIBUTE_NOINLINE;

	// Returns `true` if the message is fatal or enabled debug-fatal.
	bool IsFatal() const;

	// Records some tombstone-type data in anticipation of `Die`.
	void PrepareToDie();
	void Die();

	void SendToLog();

	// Checks `FLAGS_log_backtrace_at` and appends a backtrace if appropriate.
	void LogBacktraceIfNeeded();

	// This should be the first data member so that its initializer captures errno
	// before any other initializers alter it (e.g. with calls to new) and so that
	// no other destructors run afterward an alter it (e.g. with calls to delete).
	absl::base_internal::ErrnoSaver errno_saver_;

	// We keep the data in a separate struct so that each instance of `LogMessage`
	// uses less stack space.
	absl::Nonnull<std::unique_ptr<LogMessageData>> data_;
	};

	// Helper class so that `AbslStringify()` can modify the LogMessage.
	class StringifySink final {
	public:
	explicit StringifySink(LogMessage& message) : message_(message) {}

	void Append(size_t count, char ch) {
	message_.CopyToEncodedBuffer<LogMessage::StringType::kNotLiteral>(ch,
	count);
	}

	void Append(absl::string_view v) {
	message_.CopyToEncodedBuffer<LogMessage::StringType::kNotLiteral>(v);
	}

	// For types that implement `AbslStringify` using `absl::Format()`.
	friend void AbslFormatFlush(absl::Nonnull<StringifySink*> sink,
	absl::string_view v) {
	sink->Append(v);
	}

	private:
	LogMessage& message_;
	};

	// Note: the following is declared `ABSL_ATTRIBUTE_NOINLINE`
	template <typename T,
	typename std::enable_if<absl::HasAbslStringify<T>::value, int>::type>
	LogMessage& LogMessage::operator<<(const T& v) {
	StringifySink sink(*this);
	// Replace with public API.
	AbslStringify(sink, v);
	return *this;
	}

	// Note: the following is declared `ABSL_ATTRIBUTE_NOINLINE`
	template <typename T,
	typename std::enable_if<!absl::HasAbslStringify<T>::value, int>::type>
	LogMessage& LogMessage::operator<<(const T& v) {
	OstreamView view(*data_);
	view.stream() << log_internal::NullGuard<T>().Guard(v);
	return *this;
	}

	template <int SIZE>
	LogMessage& LogMessage::operator<<(const char (&buf)[SIZE]) {
	CopyToEncodedBuffer<StringType::kLiteral>(buf);
	return *this;
	}

	// Note: the following is declared `ABSL_ATTRIBUTE_NOINLINE`
	template <int SIZE>
	LogMessage& LogMessage::operator<<(char (&buf)[SIZE]) {
	CopyToEncodedBuffer<StringType::kNotLiteral>(buf);
	return *this;
	}
	// We instantiate these specializations in the library's TU to save space in
	// other TUs. Since the template is marked `ABSL_ATTRIBUTE_NOINLINE` we will be
	// emitting a function call either way.
	// NOLINTBEGIN(runtime/int)
	// NOLINTBEGIN(google-runtime-int)
	extern template LogMessage& LogMessage::operator<<(const char& v);
	extern template LogMessage& LogMessage::operator<<(const signed char& v);
	extern template LogMessage& LogMessage::operator<<(const unsigned char& v);
	extern template LogMessage& LogMessage::operator<<(const short& v);
	extern template LogMessage& LogMessage::operator<<(const unsigned short& v);
	extern template LogMessage& LogMessage::operator<<(const int& v);
	extern template LogMessage& LogMessage::operator<<(const unsigned int& v);
	extern template LogMessage& LogMessage::operator<<(const long& v);
	extern template LogMessage& LogMessage::operator<<(const unsigned long& v);
	extern template LogMessage& LogMessage::operator<<(const long long& v);
	extern template LogMessage& LogMessage::operator<<(const unsigned long long& v);
	extern template LogMessage& LogMessage::operator<<(
	absl::Nullable<void*> const& v);
	extern template LogMessage& LogMessage::operator<<(
	absl::Nullable<const void*> const& v);
	extern template LogMessage& LogMessage::operator<<(const float& v);
	extern template LogMessage& LogMessage::operator<<(const double& v);
	extern template LogMessage& LogMessage::operator<<(const bool& v);
	// NOLINTEND(google-runtime-int)
	// NOLINTEND(runtime/int)

	extern template void LogMessage::CopyToEncodedBuffer<
	LogMessage::StringType::kLiteral>(absl::string_view str);
	extern template void LogMessage::CopyToEncodedBuffer<
	LogMessage::StringType::kNotLiteral>(absl::string_view str);
	extern template void
	LogMessage::CopyToEncodedBuffer<LogMessage::StringType::kLiteral>(char ch,
	size_t num);
	extern template void LogMessage::CopyToEncodedBuffer<
	LogMessage::StringType::kNotLiteral>(char ch, size_t num);

	// `LogMessageFatal` ensures the process will exit in failure after logging this
	// message.
	class LogMessageFatal final : public LogMessage {
	public:
	LogMessageFatal(absl::Nonnull<const char*> file,
	int line) ABSL_ATTRIBUTE_COLD;
	LogMessageFatal(absl::Nonnull<const char*> file, int line,
	absl::string_view failure_msg) ABSL_ATTRIBUTE_COLD;
	[[noreturn]] ~LogMessageFatal();
	};

	// `LogMessageDebugFatal` ensures the process will exit in failure after logging
	// this message. It matches LogMessageFatal but is not [[noreturn]] as it's used
	// for DLOG(FATAL) variants.
	class LogMessageDebugFatal final : public LogMessage {
	public:
	LogMessageDebugFatal(absl::Nonnull<const char*> file,
	int line) ABSL_ATTRIBUTE_COLD;
	~LogMessageDebugFatal();
	};

	class LogMessageQuietlyDebugFatal final : public LogMessage {
	public:
	// DLOG(QFATAL) calls this instead of LogMessageQuietlyFatal to make sure the
	// destructor is not [[noreturn]] even if this is always FATAL as this is only
	// invoked when DLOG() is enabled.
	LogMessageQuietlyDebugFatal(absl::Nonnull<const char*> file,
	int line) ABSL_ATTRIBUTE_COLD;
	~LogMessageQuietlyDebugFatal();
	};

	// Used for LOG(QFATAL) to make sure it's properly understood as [[noreturn]].
	class LogMessageQuietlyFatal final : public LogMessage {
	public:
	LogMessageQuietlyFatal(absl::Nonnull<const char*> file,
	int line) ABSL_ATTRIBUTE_COLD;
	LogMessageQuietlyFatal(absl::Nonnull<const char*> file, int line,
	absl::string_view failure_msg) ABSL_ATTRIBUTE_COLD;
	[[noreturn]] ~LogMessageQuietlyFatal();
	};

	} // namespace log_internal
	ABSL_NAMESPACE_END
	} // namespace absl

	extern "C" ABSL_ATTRIBUTE_WEAK void ABSL_INTERNAL_C_SYMBOL(
	AbslInternalOnFatalLogMessage)(const absl::LogEntry&);

	#endif // ABSL_LOG_INTERNAL_LOG_MESSAGE_H_