absl/log/log.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/log.h
 // -----------------------------------------------------------------------------
 //
 // This header declares a family of LOG macros.
 //
 // Basic invocation looks like this:
 //
 //   LOG(INFO) << "Found " << num_cookies << " cookies";
 //
 // Most `LOG` macros take a severity level argument.  The severity levels are
 // `INFO`, `WARNING`, `ERROR`, and `FATAL`.  They are defined
 // in absl/base/log_severity.h.
 // * The `FATAL` severity level terminates the program with a stack trace after
 //   logging its message.  Error handlers registered with `RunOnFailure`
 //   (process_state.h) are run, but exit handlers registered with `atexit(3)`
 //   are not.
 // * The `QFATAL` pseudo-severity level is equivalent to `FATAL` but triggers
 //   quieter termination messages, e.g. without a full stack trace, and skips
 //   running registered error handlers.
 // * The `DFATAL` pseudo-severity level is defined as `FATAL` in debug mode and
 //   as `ERROR` otherwise.
 // Some preprocessor shenanigans are used to ensure that e.g. `LOG(INFO)` has
 // the same meaning even if a local symbol or preprocessor macro named `INFO` is
 // defined.  To specify a severity level using an expression instead of a
 // literal, use `LEVEL(expr)`.
 // Example:
 //
 //   LOG(LEVEL(stale ? absl::LogSeverity::kWarning : absl::LogSeverity::kInfo))
 //       << "Cookies are " << days << " days old";

 // `LOG` macros evaluate to an unterminated statement.  The value at the end of
 // the statement supports some chainable methods:
 //
 //   * .AtLocation(absl::string_view file, int line)
 //     .AtLocation(absl::SourceLocation loc)
 //     Overrides the location inferred from the callsite.  The string pointed to
 //     by `file` must be valid until the end of the statement.
 //   * .NoPrefix()
 //     Omits the prefix from this line.  The prefix includes metadata about the
 //     logged data such as source code location and timestamp.
 //   * .WithVerbosity(int verbose_level)
 //     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 `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.
 //   * .WithTimestamp(absl::Time timestamp)
 //     Uses the specified timestamp instead of one collected at the time of
 //     execution.
 //   * .WithThreadID(absl::LogEntry::tid_t tid)
 //     Uses the specified thread ID instead of one collected at the time of
 //     execution.
 //   * .WithMetadataFrom(const absl::LogEntry &entry)
 //     Copies all metadata (but no data) from the specified `absl::LogEntry`.
 //     This can be used to change the severity of a message, but it has some
 //     limitations:
 //     * `ABSL_MIN_LOG_LEVEL` is evaluated against the severity passed into
 //       `LOG` (or the implicit `FATAL` level of `CHECK`).
 //     * `LOG(FATAL)` and `CHECK` terminate the process unconditionally, even if
 //       the severity is changed later.
 //     `.WithMetadataFrom(entry)` should almost always be used in combination
 //     with `LOG(LEVEL(entry.log_severity()))`.
 //   * .WithPerror()
 //     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`.
 //   * .ToSinkAlso(absl::LogSink* sink)
 //     Sends this message to `*sink` in addition to whatever other sinks it
 //     would otherwise have been sent to.  `sink` must not be null.
 //   * .ToSinkOnly(absl::LogSink* sink)
 //     Sends this message to `*sink` and no others.  `sink` must not be null.
 //
 // No interfaces in this header are async-signal-safe; their use in signal
 // handlers is unsupported and may deadlock your program or eat your lunch.
 //
 // Many logging statements are inherently conditional.  For example,
 // `LOG_IF(INFO, !foo)` does nothing if `foo` is true.  Even seemingly
 // unconditional statements like `LOG(INFO)` might be disabled at
 // compile-time to minimize binary size or for security reasons.
 //
 // * Except for the condition in a `CHECK` or `QCHECK` statement, programs must
 //   not rely on evaluation of expressions anywhere in logging statements for
 //   correctness.  For example, this is ok:
 //
 //     CHECK((fp = fopen("config.ini", "r")) != nullptr);
 //
 //   But this is probably not ok:
 //
 //     LOG(INFO) << "Server status: " << StartServerAndReturnStatusString();
 //
 //   The example below is bad too; the `i++` in the `LOG_IF` condition might
 //   not be evaluated, resulting in an infinite loop:
 //
 //     for (int i = 0; i < 1000000;)
 //       LOG_IF(INFO, i++ % 1000 == 0) << "Still working...";
 //
 // * Except where otherwise noted, conditions which cause a statement not to log
 //   also cause expressions not to be evaluated.  Programs may rely on this for
 //   performance reasons, e.g. by streaming the result of an expensive function
 //   call into a `DLOG` or `LOG_EVERY_N` statement.
 // * Care has been taken to ensure that expressions are parsed by the compiler
 //   even if they are never evaluated.  This means that syntax errors will be
 //   caught and variables will be considered used for the purposes of
 //   unused-variable diagnostics.  For example, this statement won't compile
 //   even if `INFO`-level logging has been compiled out:
 //
 //     int number_of_cakes = 40;
 //     LOG(INFO) << "Number of cakes: " << number_of_cake;  // Note the typo!
 //
 //   Similarly, this won't produce unused-variable compiler diagnostics even
 //   if `INFO`-level logging is compiled out:
 //
 //     {
 //       char fox_line1[] = "Hatee-hatee-hatee-ho!";
 //       LOG_IF(ERROR, false) << "The fox says " << fox_line1;
 //       char fox_line2[] = "A-oo-oo-oo-ooo!";
 //       LOG(INFO) << "The fox also says " << fox_line2;
 //     }
 //
 //   This error-checking is not perfect; for example, symbols that have been
 //   declared but not defined may not produce link errors if used in logging
 //   statements that compile away.
 //
 // Expressions streamed into these macros are formatted using `operator<<` just
 // as they would be if streamed into a `std::ostream`, however it should be
 // noted that their actual type is unspecified.
 //
 // To implement a custom formatting operator for a type you own, there are two
 // options: `AbslStringify()` or `std::ostream& operator<<(std::ostream&, ...)`.
 // It is recommended that users make their types loggable through
 // `AbslStringify()` as it is a universal stringification extension that also
 // enables `absl::StrFormat` and `absl::StrCat` support. If both
 // `AbslStringify()` and `std::ostream& operator<<(std::ostream&, ...)` are
 // defined, `AbslStringify()` will be used.
 //
 // To use the `AbslStringify()` API, define a friend function template in your
 // type's namespace with the following signature:
 //
 //   template <typename Sink>
 //   void AbslStringify(Sink& sink, const UserDefinedType& value);
 //
 // `Sink` has the same interface as `absl::FormatSink`, but without
 // `PutPaddedString()`.
 //
 // Example:
 //
 //   struct Point {
 //     template <typename Sink>
 //     friend void AbslStringify(Sink& sink, const Point& p) {
 //       absl::Format(&sink, "(%v, %v)", p.x, p.y);
 //     }
 //
 //     int x;
 //     int y;
 //   };
 //
 // To use `std::ostream& operator<<(std::ostream&, ...)`, define
 // `std::ostream& operator<<(std::ostream&, ...)` in your type's namespace (for
 // ADL) just as you would to stream it to `std::cout`.
 //
 // Currently `AbslStringify()` ignores output manipulators but this is not
 // guaranteed behavior and may be subject to change in the future. If you would
 // like guaranteed behavior regarding output manipulators, please use
 // `std::ostream& operator<<(std::ostream&, ...)` to make custom types loggable
 // instead.
 //
 // Those macros that support streaming honor output manipulators and `fmtflag`
 // changes that output data (e.g. `std::ends`) or control formatting of data
 // (e.g. `std::hex` and `std::fixed`), however flushing such a stream is
 // ignored.  The message produced by a log statement is sent to registered
 // `absl::LogSink` instances at the end of the statement; those sinks are
 // responsible for their own flushing (e.g. to disk) semantics.
 //
 // Flag settings are not carried over from one `LOG` statement to the next; this
 // is a bit different than e.g. `std::cout`:
 //
 //   LOG(INFO) << std::hex << 0xdeadbeef;  // logs "0xdeadbeef"
 //   LOG(INFO) << 0xdeadbeef;              // logs "3735928559"

 #ifndef ABSL_LOG_LOG_H_
 #define ABSL_LOG_LOG_H_

 #include "absl/log/internal/log_impl.h"

 // LOG()
 //
 // `LOG` takes a single argument which is a severity level.  Data streamed in
 // comprise the logged message.
 // Example:
 //
 //   LOG(INFO) << "Found " << num_cookies << " cookies";
 #define LOG(severity) ABSL_LOG_INTERNAL_LOG_IMPL(_##severity)

 // PLOG()
 //
 // `PLOG` behaves like `LOG` except that a description of the current state of
 // `errno` is appended to the streamed message.
 #define PLOG(severity) ABSL_LOG_INTERNAL_PLOG_IMPL(_##severity)

 // DLOG()
 //
 // `DLOG` behaves like `LOG` in debug mode (i.e. `#ifndef NDEBUG`).  Otherwise
 // it compiles away and does nothing.  Note that `DLOG(FATAL)` does not
 // terminate the program if `NDEBUG` is defined.
 #define DLOG(severity) ABSL_LOG_INTERNAL_DLOG_IMPL(_##severity)

 // `VLOG` uses numeric levels to provide verbose logging that can configured at
 // runtime, including at a per-module level.  `VLOG` statements are logged at
 // `INFO` severity if they are logged at all; the numeric levels are on a
 // different scale than the proper severity levels.  Positive levels are
 // disabled by default.  Negative levels should not be used.
 // Example:
 //
 //   VLOG(1) << "I print when you run the program with --v=1 or higher";
 //   VLOG(2) << "I print when you run the program with --v=2 or higher";
 //
 // See vlog_is_on.h for further documentation, including the usage of the
 // --vmodule flag to log at different levels in different source files.
 //
 // `VLOG` does not produce any output when verbose logging is not enabled.
 // However, simply testing whether verbose logging is enabled can be expensive.
 // If you don't intend to enable verbose logging in non-debug builds, consider
 // using `DVLOG` instead.
 #define VLOG(severity) ABSL_LOG_INTERNAL_VLOG_IMPL(severity)

 // `DVLOG` behaves like `VLOG` in debug mode (i.e. `#ifndef NDEBUG`).
 // Otherwise, it compiles away and does nothing.
 #define DVLOG(severity) ABSL_LOG_INTERNAL_DVLOG_IMPL(severity)

 // `LOG_IF` and friends add a second argument which specifies a condition.  If
 // the condition is false, nothing is logged.
 // Example:
 //
 //   LOG_IF(INFO, num_cookies > 10) << "Got lots of cookies";
 //
 // There is no `VLOG_IF` because the order of evaluation of the arguments is
 // ambiguous and the alternate spelling with an `if`-statement is trivial.
 #define LOG_IF(severity, condition) \
   ABSL_LOG_INTERNAL_LOG_IF_IMPL(_##severity, condition)
 #define PLOG_IF(severity, condition) \
   ABSL_LOG_INTERNAL_PLOG_IF_IMPL(_##severity, condition)
 #define DLOG_IF(severity, condition) \
   ABSL_LOG_INTERNAL_DLOG_IF_IMPL(_##severity, condition)

 // LOG_EVERY_N
 //
 // An instance of `LOG_EVERY_N` increments a hidden zero-initialized counter
 // every time execution passes through it and logs the specified message when
 // the counter's value is a multiple of `n`, doing nothing otherwise.  Each
 // instance has its own counter.  The counter's value can be logged by streaming
 // the symbol `COUNTER`.  `LOG_EVERY_N` is thread-safe.
 // Example:
 //
 //   LOG_EVERY_N(WARNING, 1000) << "Got a packet with a bad CRC (" << COUNTER
 //                              << " total)";
 #define LOG_EVERY_N(severity, n) \
   ABSL_LOG_INTERNAL_LOG_EVERY_N_IMPL(_##severity, n)

 // LOG_FIRST_N
 //
 // `LOG_FIRST_N` behaves like `LOG_EVERY_N` except that the specified message is
 // logged when the counter's value is less than `n`.  `LOG_FIRST_N` is
 // thread-safe.
 #define LOG_FIRST_N(severity, n) \
   ABSL_LOG_INTERNAL_LOG_FIRST_N_IMPL(_##severity, n)

 // LOG_EVERY_POW_2
 //
 // `LOG_EVERY_POW_2` behaves like `LOG_EVERY_N` except that the specified
 // message is logged when the counter's value is a power of 2.
 // `LOG_EVERY_POW_2` is thread-safe.
 #define LOG_EVERY_POW_2(severity) \
   ABSL_LOG_INTERNAL_LOG_EVERY_POW_2_IMPL(_##severity)

 // LOG_EVERY_N_SEC
 //
 // An instance of `LOG_EVERY_N_SEC` uses a hidden state variable to log the
 // specified message at most once every `n_seconds`.  A hidden counter of
 // executions (whether a message is logged or not) is also maintained and can be
 // logged by streaming the symbol `COUNTER`.  `LOG_EVERY_N_SEC` is thread-safe.
 // Example:
 //
 //   LOG_EVERY_N_SEC(INFO, 2.5) << "Got " << COUNTER << " cookies so far";
 #define LOG_EVERY_N_SEC(severity, n_seconds) \
   ABSL_LOG_INTERNAL_LOG_EVERY_N_SEC_IMPL(_##severity, n_seconds)

 #define PLOG_EVERY_N(severity, n) \
   ABSL_LOG_INTERNAL_PLOG_EVERY_N_IMPL(_##severity, n)
 #define PLOG_FIRST_N(severity, n) \
   ABSL_LOG_INTERNAL_PLOG_FIRST_N_IMPL(_##severity, n)
 #define PLOG_EVERY_POW_2(severity) \
   ABSL_LOG_INTERNAL_PLOG_EVERY_POW_2_IMPL(_##severity)
 #define PLOG_EVERY_N_SEC(severity, n_seconds) \
   ABSL_LOG_INTERNAL_PLOG_EVERY_N_SEC_IMPL(_##severity, n_seconds)

 #define DLOG_EVERY_N(severity, n) \
   ABSL_LOG_INTERNAL_DLOG_EVERY_N_IMPL(_##severity, n)
 #define DLOG_FIRST_N(severity, n) \
   ABSL_LOG_INTERNAL_DLOG_FIRST_N_IMPL(_##severity, n)
 #define DLOG_EVERY_POW_2(severity) \
   ABSL_LOG_INTERNAL_DLOG_EVERY_POW_2_IMPL(_##severity)
 #define DLOG_EVERY_N_SEC(severity, n_seconds) \
   ABSL_LOG_INTERNAL_DLOG_EVERY_N_SEC_IMPL(_##severity, n_seconds)

 #define VLOG_EVERY_N(severity, n) \
   ABSL_LOG_INTERNAL_VLOG_EVERY_N_IMPL(severity, n)
 #define VLOG_FIRST_N(severity, n) \
   ABSL_LOG_INTERNAL_VLOG_FIRST_N_IMPL(severity, n)
 #define VLOG_EVERY_POW_2(severity) \
   ABSL_LOG_INTERNAL_VLOG_EVERY_POW_2_IMPL(severity)
 #define VLOG_EVERY_N_SEC(severity, n_seconds) \
   ABSL_LOG_INTERNAL_VLOG_EVERY_N_SEC_IMPL(severity, n_seconds)

 // `LOG_IF_EVERY_N` and friends behave as the corresponding `LOG_EVERY_N`
 // but neither increment a counter nor log a message if condition is false (as
 // `LOG_IF`).
 // Example:
 //
 //   LOG_IF_EVERY_N(INFO, (size > 1024), 10) << "Got the " << COUNTER
 //                                           << "th big cookie";
 #define LOG_IF_EVERY_N(severity, condition, n) \
   ABSL_LOG_INTERNAL_LOG_IF_EVERY_N_IMPL(_##severity, condition, n)
 #define LOG_IF_FIRST_N(severity, condition, n) \
   ABSL_LOG_INTERNAL_LOG_IF_FIRST_N_IMPL(_##severity, condition, n)
 #define LOG_IF_EVERY_POW_2(severity, condition) \
   ABSL_LOG_INTERNAL_LOG_IF_EVERY_POW_2_IMPL(_##severity, condition)
 #define LOG_IF_EVERY_N_SEC(severity, condition, n_seconds) \
   ABSL_LOG_INTERNAL_LOG_IF_EVERY_N_SEC_IMPL(_##severity, condition, n_seconds)

 #define PLOG_IF_EVERY_N(severity, condition, n) \
   ABSL_LOG_INTERNAL_PLOG_IF_EVERY_N_IMPL(_##severity, condition, n)
 #define PLOG_IF_FIRST_N(severity, condition, n) \
   ABSL_LOG_INTERNAL_PLOG_IF_FIRST_N_IMPL(_##severity, condition, n)
 #define PLOG_IF_EVERY_POW_2(severity, condition) \
   ABSL_LOG_INTERNAL_PLOG_IF_EVERY_POW_2_IMPL(_##severity, condition)
 #define PLOG_IF_EVERY_N_SEC(severity, condition, n_seconds) \
   ABSL_LOG_INTERNAL_PLOG_IF_EVERY_N_SEC_IMPL(_##severity, condition, n_seconds)

 #define DLOG_IF_EVERY_N(severity, condition, n) \
   ABSL_LOG_INTERNAL_DLOG_IF_EVERY_N_IMPL(_##severity, condition, n)
 #define DLOG_IF_FIRST_N(severity, condition, n) \
   ABSL_LOG_INTERNAL_DLOG_IF_FIRST_N_IMPL(_##severity, condition, n)
 #define DLOG_IF_EVERY_POW_2(severity, condition) \
   ABSL_LOG_INTERNAL_DLOG_IF_EVERY_POW_2_IMPL(_##severity, condition)
 #define DLOG_IF_EVERY_N_SEC(severity, condition, n_seconds) \
   ABSL_LOG_INTERNAL_DLOG_IF_EVERY_N_SEC_IMPL(_##severity, condition, n_seconds)

 #endif  // ABSL_LOG_LOG_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/log.h
	// -----------------------------------------------------------------------------
	//
	// This header declares a family of LOG macros.
	//
	// Basic invocation looks like this:
	//
	// LOG(INFO) << "Found " << num_cookies << " cookies";
	//
	// Most `LOG` macros take a severity level argument. The severity levels are
	// `INFO`, `WARNING`, `ERROR`, and `FATAL`. They are defined
	// in absl/base/log_severity.h.
	// * The `FATAL` severity level terminates the program with a stack trace after
	// logging its message. Error handlers registered with `RunOnFailure`
	// (process_state.h) are run, but exit handlers registered with `atexit(3)`
	// are not.
	// * The `QFATAL` pseudo-severity level is equivalent to `FATAL` but triggers
	// quieter termination messages, e.g. without a full stack trace, and skips
	// running registered error handlers.
	// * The `DFATAL` pseudo-severity level is defined as `FATAL` in debug mode and
	// as `ERROR` otherwise.
	// Some preprocessor shenanigans are used to ensure that e.g. `LOG(INFO)` has
	// the same meaning even if a local symbol or preprocessor macro named `INFO` is
	// defined. To specify a severity level using an expression instead of a
	// literal, use `LEVEL(expr)`.
	// Example:
	//
	// LOG(LEVEL(stale ? absl::LogSeverity::kWarning : absl::LogSeverity::kInfo))
	// << "Cookies are " << days << " days old";

	// `LOG` macros evaluate to an unterminated statement. The value at the end of
	// the statement supports some chainable methods:
	//
	// * .AtLocation(absl::string_view file, int line)
	// .AtLocation(absl::SourceLocation loc)
	// Overrides the location inferred from the callsite. The string pointed to
	// by `file` must be valid until the end of the statement.
	// * .NoPrefix()
	// Omits the prefix from this line. The prefix includes metadata about the
	// logged data such as source code location and timestamp.
	// * .WithVerbosity(int verbose_level)
	// 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 `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.
	// * .WithTimestamp(absl::Time timestamp)
	// Uses the specified timestamp instead of one collected at the time of
	// execution.
	// * .WithThreadID(absl::LogEntry::tid_t tid)
	// Uses the specified thread ID instead of one collected at the time of
	// execution.
	// * .WithMetadataFrom(const absl::LogEntry &entry)
	// Copies all metadata (but no data) from the specified `absl::LogEntry`.
	// This can be used to change the severity of a message, but it has some
	// limitations:
	// * `ABSL_MIN_LOG_LEVEL` is evaluated against the severity passed into
	// `LOG` (or the implicit `FATAL` level of `CHECK`).
	// * `LOG(FATAL)` and `CHECK` terminate the process unconditionally, even if
	// the severity is changed later.
	// `.WithMetadataFrom(entry)` should almost always be used in combination
	// with `LOG(LEVEL(entry.log_severity()))`.
	// * .WithPerror()
	// 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`.
	// * .ToSinkAlso(absl::LogSink* sink)
	// Sends this message to `*sink` in addition to whatever other sinks it
	// would otherwise have been sent to. `sink` must not be null.
	// * .ToSinkOnly(absl::LogSink* sink)
	// Sends this message to `*sink` and no others. `sink` must not be null.
	//
	// No interfaces in this header are async-signal-safe; their use in signal
	// handlers is unsupported and may deadlock your program or eat your lunch.
	//
	// Many logging statements are inherently conditional. For example,
	// `LOG_IF(INFO, !foo)` does nothing if `foo` is true. Even seemingly
	// unconditional statements like `LOG(INFO)` might be disabled at
	// compile-time to minimize binary size or for security reasons.
	//
	// * Except for the condition in a `CHECK` or `QCHECK` statement, programs must
	// not rely on evaluation of expressions anywhere in logging statements for
	// correctness. For example, this is ok:
	//
	// CHECK((fp = fopen("config.ini", "r")) != nullptr);
	//
	// But this is probably not ok:
	//
	// LOG(INFO) << "Server status: " << StartServerAndReturnStatusString();
	//
	// The example below is bad too; the `i++` in the `LOG_IF` condition might
	// not be evaluated, resulting in an infinite loop:
	//
	// for (int i = 0; i < 1000000;)
	// LOG_IF(INFO, i++ % 1000 == 0) << "Still working...";
	//
	// * Except where otherwise noted, conditions which cause a statement not to log
	// also cause expressions not to be evaluated. Programs may rely on this for
	// performance reasons, e.g. by streaming the result of an expensive function
	// call into a `DLOG` or `LOG_EVERY_N` statement.
	// * Care has been taken to ensure that expressions are parsed by the compiler
	// even if they are never evaluated. This means that syntax errors will be
	// caught and variables will be considered used for the purposes of
	// unused-variable diagnostics. For example, this statement won't compile
	// even if `INFO`-level logging has been compiled out:
	//
	// int number_of_cakes = 40;
	// LOG(INFO) << "Number of cakes: " << number_of_cake; // Note the typo!
	//
	// Similarly, this won't produce unused-variable compiler diagnostics even
	// if `INFO`-level logging is compiled out:
	//
	// {
	// char fox_line1[] = "Hatee-hatee-hatee-ho!";
	// LOG_IF(ERROR, false) << "The fox says " << fox_line1;
	// char fox_line2[] = "A-oo-oo-oo-ooo!";
	// LOG(INFO) << "The fox also says " << fox_line2;
	// }
	//
	// This error-checking is not perfect; for example, symbols that have been
	// declared but not defined may not produce link errors if used in logging
	// statements that compile away.
	//
	// Expressions streamed into these macros are formatted using `operator<<` just
	// as they would be if streamed into a `std::ostream`, however it should be
	// noted that their actual type is unspecified.
	//
	// To implement a custom formatting operator for a type you own, there are two
	// options: `AbslStringify()` or `std::ostream& operator<<(std::ostream&, ...)`.
	// It is recommended that users make their types loggable through
	// `AbslStringify()` as it is a universal stringification extension that also
	// enables `absl::StrFormat` and `absl::StrCat` support. If both
	// `AbslStringify()` and `std::ostream& operator<<(std::ostream&, ...)` are
	// defined, `AbslStringify()` will be used.
	//
	// To use the `AbslStringify()` API, define a friend function template in your
	// type's namespace with the following signature:
	//
	// template <typename Sink>
	// void AbslStringify(Sink& sink, const UserDefinedType& value);
	//
	// `Sink` has the same interface as `absl::FormatSink`, but without
	// `PutPaddedString()`.
	//
	// Example:
	//
	// struct Point {
	// template <typename Sink>
	// friend void AbslStringify(Sink& sink, const Point& p) {
	// absl::Format(&sink, "(%v, %v)", p.x, p.y);
	// }
	//
	// int x;
	// int y;
	// };
	//
	// To use `std::ostream& operator<<(std::ostream&, ...)`, define
	// `std::ostream& operator<<(std::ostream&, ...)` in your type's namespace (for
	// ADL) just as you would to stream it to `std::cout`.
	//
	// Currently `AbslStringify()` ignores output manipulators but this is not
	// guaranteed behavior and may be subject to change in the future. If you would
	// like guaranteed behavior regarding output manipulators, please use
	// `std::ostream& operator<<(std::ostream&, ...)` to make custom types loggable
	// instead.
	//
	// Those macros that support streaming honor output manipulators and `fmtflag`
	// changes that output data (e.g. `std::ends`) or control formatting of data
	// (e.g. `std::hex` and `std::fixed`), however flushing such a stream is
	// ignored. The message produced by a log statement is sent to registered
	// `absl::LogSink` instances at the end of the statement; those sinks are
	// responsible for their own flushing (e.g. to disk) semantics.
	//
	// Flag settings are not carried over from one `LOG` statement to the next; this
	// is a bit different than e.g. `std::cout`:
	//
	// LOG(INFO) << std::hex << 0xdeadbeef; // logs "0xdeadbeef"
	// LOG(INFO) << 0xdeadbeef; // logs "3735928559"

	#ifndef ABSL_LOG_LOG_H_
	#define ABSL_LOG_LOG_H_

	#include "absl/log/internal/log_impl.h"

	// LOG()
	//
	// `LOG` takes a single argument which is a severity level. Data streamed in
	// comprise the logged message.
	// Example:
	//
	// LOG(INFO) << "Found " << num_cookies << " cookies";
	#define LOG(severity) ABSL_LOG_INTERNAL_LOG_IMPL(_##severity)

	// PLOG()
	//
	// `PLOG` behaves like `LOG` except that a description of the current state of
	// `errno` is appended to the streamed message.
	#define PLOG(severity) ABSL_LOG_INTERNAL_PLOG_IMPL(_##severity)

	// DLOG()
	//
	// `DLOG` behaves like `LOG` in debug mode (i.e. `#ifndef NDEBUG`). Otherwise
	// it compiles away and does nothing. Note that `DLOG(FATAL)` does not
	// terminate the program if `NDEBUG` is defined.
	#define DLOG(severity) ABSL_LOG_INTERNAL_DLOG_IMPL(_##severity)

	// `VLOG` uses numeric levels to provide verbose logging that can configured at
	// runtime, including at a per-module level. `VLOG` statements are logged at
	// `INFO` severity if they are logged at all; the numeric levels are on a
	// different scale than the proper severity levels. Positive levels are
	// disabled by default. Negative levels should not be used.
	// Example:
	//
	// VLOG(1) << "I print when you run the program with --v=1 or higher";
	// VLOG(2) << "I print when you run the program with --v=2 or higher";
	//
	// See vlog_is_on.h for further documentation, including the usage of the
	// --vmodule flag to log at different levels in different source files.
	//
	// `VLOG` does not produce any output when verbose logging is not enabled.
	// However, simply testing whether verbose logging is enabled can be expensive.
	// If you don't intend to enable verbose logging in non-debug builds, consider
	// using `DVLOG` instead.
	#define VLOG(severity) ABSL_LOG_INTERNAL_VLOG_IMPL(severity)

	// `DVLOG` behaves like `VLOG` in debug mode (i.e. `#ifndef NDEBUG`).
	// Otherwise, it compiles away and does nothing.
	#define DVLOG(severity) ABSL_LOG_INTERNAL_DVLOG_IMPL(severity)

	// `LOG_IF` and friends add a second argument which specifies a condition. If
	// the condition is false, nothing is logged.
	// Example:
	//
	// LOG_IF(INFO, num_cookies > 10) << "Got lots of cookies";
	//
	// There is no `VLOG_IF` because the order of evaluation of the arguments is
	// ambiguous and the alternate spelling with an `if`-statement is trivial.
	#define LOG_IF(severity, condition) \
	ABSL_LOG_INTERNAL_LOG_IF_IMPL(_##severity, condition)
	#define PLOG_IF(severity, condition) \
	ABSL_LOG_INTERNAL_PLOG_IF_IMPL(_##severity, condition)
	#define DLOG_IF(severity, condition) \
	ABSL_LOG_INTERNAL_DLOG_IF_IMPL(_##severity, condition)

	// LOG_EVERY_N
	//
	// An instance of `LOG_EVERY_N` increments a hidden zero-initialized counter
	// every time execution passes through it and logs the specified message when
	// the counter's value is a multiple of `n`, doing nothing otherwise. Each
	// instance has its own counter. The counter's value can be logged by streaming
	// the symbol `COUNTER`. `LOG_EVERY_N` is thread-safe.
	// Example:
	//
	// LOG_EVERY_N(WARNING, 1000) << "Got a packet with a bad CRC (" << COUNTER
	// << " total)";
	#define LOG_EVERY_N(severity, n) \
	ABSL_LOG_INTERNAL_LOG_EVERY_N_IMPL(_##severity, n)

	// LOG_FIRST_N
	//
	// `LOG_FIRST_N` behaves like `LOG_EVERY_N` except that the specified message is
	// logged when the counter's value is less than `n`. `LOG_FIRST_N` is
	// thread-safe.
	#define LOG_FIRST_N(severity, n) \
	ABSL_LOG_INTERNAL_LOG_FIRST_N_IMPL(_##severity, n)

	// LOG_EVERY_POW_2
	//
	// `LOG_EVERY_POW_2` behaves like `LOG_EVERY_N` except that the specified
	// message is logged when the counter's value is a power of 2.
	// `LOG_EVERY_POW_2` is thread-safe.
	#define LOG_EVERY_POW_2(severity) \
	ABSL_LOG_INTERNAL_LOG_EVERY_POW_2_IMPL(_##severity)

	// LOG_EVERY_N_SEC
	//
	// An instance of `LOG_EVERY_N_SEC` uses a hidden state variable to log the
	// specified message at most once every `n_seconds`. A hidden counter of
	// executions (whether a message is logged or not) is also maintained and can be
	// logged by streaming the symbol `COUNTER`. `LOG_EVERY_N_SEC` is thread-safe.
	// Example:
	//
	// LOG_EVERY_N_SEC(INFO, 2.5) << "Got " << COUNTER << " cookies so far";
	#define LOG_EVERY_N_SEC(severity, n_seconds) \
	ABSL_LOG_INTERNAL_LOG_EVERY_N_SEC_IMPL(_##severity, n_seconds)

	#define PLOG_EVERY_N(severity, n) \
	ABSL_LOG_INTERNAL_PLOG_EVERY_N_IMPL(_##severity, n)
	#define PLOG_FIRST_N(severity, n) \
	ABSL_LOG_INTERNAL_PLOG_FIRST_N_IMPL(_##severity, n)
	#define PLOG_EVERY_POW_2(severity) \
	ABSL_LOG_INTERNAL_PLOG_EVERY_POW_2_IMPL(_##severity)
	#define PLOG_EVERY_N_SEC(severity, n_seconds) \
	ABSL_LOG_INTERNAL_PLOG_EVERY_N_SEC_IMPL(_##severity, n_seconds)

	#define DLOG_EVERY_N(severity, n) \
	ABSL_LOG_INTERNAL_DLOG_EVERY_N_IMPL(_##severity, n)
	#define DLOG_FIRST_N(severity, n) \
	ABSL_LOG_INTERNAL_DLOG_FIRST_N_IMPL(_##severity, n)
	#define DLOG_EVERY_POW_2(severity) \
	ABSL_LOG_INTERNAL_DLOG_EVERY_POW_2_IMPL(_##severity)
	#define DLOG_EVERY_N_SEC(severity, n_seconds) \
	ABSL_LOG_INTERNAL_DLOG_EVERY_N_SEC_IMPL(_##severity, n_seconds)

	#define VLOG_EVERY_N(severity, n) \
	ABSL_LOG_INTERNAL_VLOG_EVERY_N_IMPL(severity, n)
	#define VLOG_FIRST_N(severity, n) \
	ABSL_LOG_INTERNAL_VLOG_FIRST_N_IMPL(severity, n)
	#define VLOG_EVERY_POW_2(severity) \
	ABSL_LOG_INTERNAL_VLOG_EVERY_POW_2_IMPL(severity)
	#define VLOG_EVERY_N_SEC(severity, n_seconds) \
	ABSL_LOG_INTERNAL_VLOG_EVERY_N_SEC_IMPL(severity, n_seconds)

	// `LOG_IF_EVERY_N` and friends behave as the corresponding `LOG_EVERY_N`
	// but neither increment a counter nor log a message if condition is false (as
	// `LOG_IF`).
	// Example:
	//
	// LOG_IF_EVERY_N(INFO, (size > 1024), 10) << "Got the " << COUNTER
	// << "th big cookie";
	#define LOG_IF_EVERY_N(severity, condition, n) \
	ABSL_LOG_INTERNAL_LOG_IF_EVERY_N_IMPL(_##severity, condition, n)
	#define LOG_IF_FIRST_N(severity, condition, n) \
	ABSL_LOG_INTERNAL_LOG_IF_FIRST_N_IMPL(_##severity, condition, n)
	#define LOG_IF_EVERY_POW_2(severity, condition) \
	ABSL_LOG_INTERNAL_LOG_IF_EVERY_POW_2_IMPL(_##severity, condition)
	#define LOG_IF_EVERY_N_SEC(severity, condition, n_seconds) \
	ABSL_LOG_INTERNAL_LOG_IF_EVERY_N_SEC_IMPL(_##severity, condition, n_seconds)

	#define PLOG_IF_EVERY_N(severity, condition, n) \
	ABSL_LOG_INTERNAL_PLOG_IF_EVERY_N_IMPL(_##severity, condition, n)
	#define PLOG_IF_FIRST_N(severity, condition, n) \
	ABSL_LOG_INTERNAL_PLOG_IF_FIRST_N_IMPL(_##severity, condition, n)
	#define PLOG_IF_EVERY_POW_2(severity, condition) \
	ABSL_LOG_INTERNAL_PLOG_IF_EVERY_POW_2_IMPL(_##severity, condition)
	#define PLOG_IF_EVERY_N_SEC(severity, condition, n_seconds) \
	ABSL_LOG_INTERNAL_PLOG_IF_EVERY_N_SEC_IMPL(_##severity, condition, n_seconds)

	#define DLOG_IF_EVERY_N(severity, condition, n) \
	ABSL_LOG_INTERNAL_DLOG_IF_EVERY_N_IMPL(_##severity, condition, n)
	#define DLOG_IF_FIRST_N(severity, condition, n) \
	ABSL_LOG_INTERNAL_DLOG_IF_FIRST_N_IMPL(_##severity, condition, n)
	#define DLOG_IF_EVERY_POW_2(severity, condition) \
	ABSL_LOG_INTERNAL_DLOG_IF_EVERY_POW_2_IMPL(_##severity, condition)
	#define DLOG_IF_EVERY_N_SEC(severity, condition, n_seconds) \
	ABSL_LOG_INTERNAL_DLOG_IF_EVERY_N_SEC_IMPL(_##severity, condition, n_seconds)

	#endif // ABSL_LOG_LOG_H_