src/third_party/protobuf/src/google/protobuf/util/time_util.cc - cobalt - Git at Google

 // Protocol Buffers - Google's data interchange format
 // Copyright 2008 Google Inc.  All rights reserved.
 // https://developers.google.com/protocol-buffers/
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 // notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 // copyright notice, this list of conditions and the following disclaimer
 // in the documentation and/or other materials provided with the
 // distribution.
 //     * Neither the name of Google Inc. nor the names of its
 // contributors may be used to endorse or promote products derived from
 // this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #include <google/protobuf/util/time_util.h>

 #include <google/protobuf/stubs/time.h>
 #include <google/protobuf/stubs/int128.h>
 #include <google/protobuf/stubs/strutil.h>
 #include <google/protobuf/stubs/stringprintf.h>
 #include <google/protobuf/duration.pb.h>
 #include <google/protobuf/timestamp.pb.h>

 namespace google {
 namespace protobuf {
 namespace util {

 using google::protobuf::Timestamp;
 using google::protobuf::Duration;

 namespace {
 static const int kNanosPerSecond = 1000000000;
 static const int kMicrosPerSecond = 1000000;
 static const int kMillisPerSecond = 1000;
 static const int kNanosPerMillisecond = 1000000;
 static const int kMicrosPerMillisecond = 1000;
 static const int kNanosPerMicrosecond = 1000;
 static const int kSecondsPerMinute = 60;  // Note that we ignore leap seconds.
 static const int kSecondsPerHour = 3600;
 static const char kTimestampFormat[] = "%E4Y-%m-%dT%H:%M:%S";

 template <typename T>
 T CreateNormalized(int64 seconds, int64 nanos);

 template <>
 Timestamp CreateNormalized(int64 seconds, int64 nanos) {
   // Make sure nanos is in the range.
   if (nanos <= -kNanosPerSecond || nanos >= kNanosPerSecond) {
     seconds += nanos / kNanosPerSecond;
     nanos = nanos % kNanosPerSecond;
   }
   // For Timestamp nanos should be in the range [0, 999999999]
   if (nanos < 0) {
     seconds -= 1;
     nanos += kNanosPerSecond;
   }
   GOOGLE_DCHECK(seconds >= TimeUtil::kTimestampMinSeconds &&
          seconds <= TimeUtil::kTimestampMaxSeconds);
   Timestamp result;
   result.set_seconds(seconds);
   result.set_nanos(static_cast<int32>(nanos));
   return result;
 }

 template <>
 Duration CreateNormalized(int64 seconds, int64 nanos) {
   // Make sure nanos is in the range.
   if (nanos <= -kNanosPerSecond || nanos >= kNanosPerSecond) {
     seconds += nanos / kNanosPerSecond;
     nanos = nanos % kNanosPerSecond;
   }
   // nanos should have the same sign as seconds.
   if (seconds < 0 && nanos > 0) {
     seconds += 1;
     nanos -= kNanosPerSecond;
   } else if (seconds > 0 && nanos < 0) {
     seconds -= 1;
     nanos += kNanosPerSecond;
   }
   GOOGLE_DCHECK(seconds >= TimeUtil::kDurationMinSeconds &&
          seconds <= TimeUtil::kDurationMaxSeconds);
   Duration result;
   result.set_seconds(seconds);
   result.set_nanos(static_cast<int32>(nanos));
   return result;
 }

 // Format nanoseconds with either 3, 6, or 9 digits depending on the required
 // precision to represent the exact value.
 string FormatNanos(int32 nanos) {
   if (nanos % kNanosPerMillisecond == 0) {
     return StringPrintf("%03d", nanos / kNanosPerMillisecond);
   } else if (nanos % kNanosPerMicrosecond == 0) {
     return StringPrintf("%06d", nanos / kNanosPerMicrosecond);
   } else {
     return StringPrintf("%09d", nanos);
   }
 }

 string FormatTime(int64 seconds, int32 nanos) {
   return ::google::protobuf::internal::FormatTime(seconds, nanos);
 }

 bool ParseTime(const string& value, int64* seconds, int32* nanos) {
   return ::google::protobuf::internal::ParseTime(value, seconds, nanos);
 }

 void CurrentTime(int64* seconds, int32* nanos) {
   return ::google::protobuf::internal::GetCurrentTime(seconds, nanos);
 }

 // Truncates the remainder part after division.
 int64 RoundTowardZero(int64 value, int64 divider) {
   int64 result = value / divider;
   int64 remainder = value % divider;
   // Before C++11, the sign of the remainder is implementation dependent if
   // any of the operands is negative. Here we try to enforce C++11's "rounded
   // toward zero" semantics. For example, for (-5) / 2 an implementation may
   // give -3 as the result with the remainder being 1. This function ensures
   // we always return -2 (closer to zero) regardless of the implementation.
   if (result < 0 && remainder > 0) {
     return result + 1;
   } else {
     return result;
   }
 }
 }  // namespace

 string TimeUtil::ToString(const Timestamp& timestamp) {
   return FormatTime(timestamp.seconds(), timestamp.nanos());
 }

 bool TimeUtil::FromString(const string& value, Timestamp* timestamp) {
   int64 seconds;
   int32 nanos;
   if (!ParseTime(value, &seconds, &nanos)) {
     return false;
   }
   *timestamp = CreateNormalized<Timestamp>(seconds, nanos);
   return true;
 }

 Timestamp TimeUtil::GetCurrentTime() {
   int64 seconds;
   int32 nanos;
   CurrentTime(&seconds, &nanos);
   return CreateNormalized<Timestamp>(seconds, nanos);
 }

 Timestamp TimeUtil::GetEpoch() { return Timestamp(); }

 string TimeUtil::ToString(const Duration& duration) {
   string result;
   int64 seconds = duration.seconds();
   int32 nanos = duration.nanos();
   if (seconds < 0 || nanos < 0) {
     result += "-";
     seconds = -seconds;
     nanos = -nanos;
   }
   result += StringPrintf("%" GOOGLE_LL_FORMAT "d", seconds);
   if (nanos != 0) {
     result += "." + FormatNanos(nanos);
   }
   result += "s";
   return result;
 }

 static int64 Pow(int64 x, int y) {
   int64 result = 1;
   for (int i = 0; i < y; ++i) {
     result *= x;
   }
   return result;
 }

 bool TimeUtil::FromString(const string& value, Duration* duration) {
   if (value.length() <= 1 || value[value.length() - 1] != 's') {
     return false;
   }
   bool negative = (value[0] == '-');
   int sign_length = (negative ? 1 : 0);
   // Parse the duration value as two integers rather than a float value
   // to avoid precision loss.
   string seconds_part, nanos_part;
   size_t pos = value.find_last_of(".");
   if (pos == string::npos) {
     seconds_part = value.substr(sign_length, value.length() - 1 - sign_length);
     nanos_part = "0";
   } else {
     seconds_part = value.substr(sign_length, pos - sign_length);
     nanos_part = value.substr(pos + 1, value.length() - pos - 2);
   }
   char* end;
   int64 seconds = strto64(seconds_part.c_str(), &end, 10);
   if (end != seconds_part.c_str() + seconds_part.length()) {
     return false;
   }
   int64 nanos = strto64(nanos_part.c_str(), &end, 10);
   if (end != nanos_part.c_str() + nanos_part.length()) {
     return false;
   }
   nanos = nanos * Pow(10, 9 - nanos_part.length());
   if (negative) {
     // If a Duration is negative, both seconds and nanos should be negative.
     seconds = -seconds;
     nanos = -nanos;
   }
   duration->set_seconds(seconds);
   duration->set_nanos(static_cast<int32>(nanos));
   return true;
 }

 Duration TimeUtil::NanosecondsToDuration(int64 nanos) {
   return CreateNormalized<Duration>(nanos / kNanosPerSecond,
                                     nanos % kNanosPerSecond);
 }

 Duration TimeUtil::MicrosecondsToDuration(int64 micros) {
   return CreateNormalized<Duration>(
       micros / kMicrosPerSecond,
       (micros % kMicrosPerSecond) * kNanosPerMicrosecond);
 }

 Duration TimeUtil::MillisecondsToDuration(int64 millis) {
   return CreateNormalized<Duration>(
       millis / kMillisPerSecond,
       (millis % kMillisPerSecond) * kNanosPerMillisecond);
 }

 Duration TimeUtil::SecondsToDuration(int64 seconds) {
   return CreateNormalized<Duration>(seconds, 0);
 }

 Duration TimeUtil::MinutesToDuration(int64 minutes) {
   return CreateNormalized<Duration>(minutes * kSecondsPerMinute, 0);
 }

 Duration TimeUtil::HoursToDuration(int64 hours) {
   return CreateNormalized<Duration>(hours * kSecondsPerHour, 0);
 }

 int64 TimeUtil::DurationToNanoseconds(const Duration& duration) {
   return duration.seconds() * kNanosPerSecond + duration.nanos();
 }

 int64 TimeUtil::DurationToMicroseconds(const Duration& duration) {
   return duration.seconds() * kMicrosPerSecond +
          RoundTowardZero(duration.nanos(), kNanosPerMicrosecond);
 }

 int64 TimeUtil::DurationToMilliseconds(const Duration& duration) {
   return duration.seconds() * kMillisPerSecond +
          RoundTowardZero(duration.nanos(), kNanosPerMillisecond);
 }

 int64 TimeUtil::DurationToSeconds(const Duration& duration) {
   return duration.seconds();
 }

 int64 TimeUtil::DurationToMinutes(const Duration& duration) {
   return RoundTowardZero(duration.seconds(), kSecondsPerMinute);
 }

 int64 TimeUtil::DurationToHours(const Duration& duration) {
   return RoundTowardZero(duration.seconds(), kSecondsPerHour);
 }

 Timestamp TimeUtil::NanosecondsToTimestamp(int64 nanos) {
   return CreateNormalized<Timestamp>(nanos / kNanosPerSecond,
                                      nanos % kNanosPerSecond);
 }

 Timestamp TimeUtil::MicrosecondsToTimestamp(int64 micros) {
   return CreateNormalized<Timestamp>(
       micros / kMicrosPerSecond,
       micros % kMicrosPerSecond * kNanosPerMicrosecond);
 }

 Timestamp TimeUtil::MillisecondsToTimestamp(int64 millis) {
   return CreateNormalized<Timestamp>(
       millis / kMillisPerSecond,
       millis % kMillisPerSecond * kNanosPerMillisecond);
 }

 Timestamp TimeUtil::SecondsToTimestamp(int64 seconds) {
   return CreateNormalized<Timestamp>(seconds, 0);
 }

 int64 TimeUtil::TimestampToNanoseconds(const Timestamp& timestamp) {
   return timestamp.seconds() * kNanosPerSecond + timestamp.nanos();
 }

 int64 TimeUtil::TimestampToMicroseconds(const Timestamp& timestamp) {
   return timestamp.seconds() * kMicrosPerSecond +
          RoundTowardZero(timestamp.nanos(), kNanosPerMicrosecond);
 }

 int64 TimeUtil::TimestampToMilliseconds(const Timestamp& timestamp) {
   return timestamp.seconds() * kMillisPerSecond +
          RoundTowardZero(timestamp.nanos(), kNanosPerMillisecond);
 }

 int64 TimeUtil::TimestampToSeconds(const Timestamp& timestamp) {
   return timestamp.seconds();
 }

 Timestamp TimeUtil::TimeTToTimestamp(time_t value) {
   return CreateNormalized<Timestamp>(static_cast<int64>(value), 0);
 }

 time_t TimeUtil::TimestampToTimeT(const Timestamp& value) {
   return static_cast<time_t>(value.seconds());
 }

 Timestamp TimeUtil::TimevalToTimestamp(const timeval& value) {
   return CreateNormalized<Timestamp>(value.tv_sec,
                                      value.tv_usec * kNanosPerMicrosecond);
 }

 timeval TimeUtil::TimestampToTimeval(const Timestamp& value) {
   timeval result;
   result.tv_sec = value.seconds();
   result.tv_usec = RoundTowardZero(value.nanos(), kNanosPerMicrosecond);
   return result;
 }

 Duration TimeUtil::TimevalToDuration(const timeval& value) {
   return CreateNormalized<Duration>(value.tv_sec,
                                     value.tv_usec * kNanosPerMicrosecond);
 }

 timeval TimeUtil::DurationToTimeval(const Duration& value) {
   timeval result;
   result.tv_sec = value.seconds();
   result.tv_usec = RoundTowardZero(value.nanos(), kNanosPerMicrosecond);
   // timeval.tv_usec's range is [0, 1000000)
   if (result.tv_usec < 0) {
     result.tv_sec -= 1;
     result.tv_usec += kMicrosPerSecond;
   }
   return result;
 }

 }  // namespace util
 }  // namespace protobuf


 namespace protobuf {
 namespace {
 using google::protobuf::util::kNanosPerSecond;
 using google::protobuf::util::CreateNormalized;

 // Convert a Timestamp to uint128.
 void ToUint128(const Timestamp& value, uint128* result, bool* negative) {
   if (value.seconds() < 0) {
     *negative = true;
     *result = static_cast<uint64>(-value.seconds());
     *result = *result * kNanosPerSecond - static_cast<uint32>(value.nanos());
   } else {
     *negative = false;
     *result = static_cast<uint64>(value.seconds());
     *result = *result * kNanosPerSecond + static_cast<uint32>(value.nanos());
   }
 }

 // Convert a Duration to uint128.
 void ToUint128(const Duration& value, uint128* result, bool* negative) {
   if (value.seconds() < 0 || value.nanos() < 0) {
     *negative = true;
     *result = static_cast<uint64>(-value.seconds());
     *result = *result * kNanosPerSecond + static_cast<uint32>(-value.nanos());
   } else {
     *negative = false;
     *result = static_cast<uint64>(value.seconds());
     *result = *result * kNanosPerSecond + static_cast<uint32>(value.nanos());
   }
 }

 void ToTimestamp(const uint128& value, bool negative, Timestamp* timestamp) {
   int64 seconds = static_cast<int64>(Uint128Low64(value / kNanosPerSecond));
   int32 nanos = static_cast<int32>(Uint128Low64(value % kNanosPerSecond));
   if (negative) {
     seconds = -seconds;
     nanos = -nanos;
     if (nanos < 0) {
       nanos += kNanosPerSecond;
       seconds -= 1;
     }
   }
   timestamp->set_seconds(seconds);
   timestamp->set_nanos(nanos);
 }

 void ToDuration(const uint128& value, bool negative, Duration* duration) {
   int64 seconds = static_cast<int64>(Uint128Low64(value / kNanosPerSecond));
   int32 nanos = static_cast<int32>(Uint128Low64(value % kNanosPerSecond));
   if (negative) {
     seconds = -seconds;
     nanos = -nanos;
   }
   duration->set_seconds(seconds);
   duration->set_nanos(nanos);
 }
 }  // namespace

 Duration& operator+=(Duration& d1, const Duration& d2) {
   d1 = CreateNormalized<Duration>(d1.seconds() + d2.seconds(),
                                   d1.nanos() + d2.nanos());
   return d1;
 }

 Duration& operator-=(Duration& d1, const Duration& d2) {  // NOLINT
   d1 = CreateNormalized<Duration>(d1.seconds() - d2.seconds(),
                                   d1.nanos() - d2.nanos());
   return d1;
 }

 Duration& operator*=(Duration& d, int64 r) {  // NOLINT
   bool negative;
   uint128 value;
   ToUint128(d, &value, &negative);
   if (r > 0) {
     value *= static_cast<uint64>(r);
   } else {
     negative = !negative;
     value *= static_cast<uint64>(-r);
   }
   ToDuration(value, negative, &d);
   return d;
 }

 Duration& operator*=(Duration& d, double r) {  // NOLINT
   double result = (d.seconds() * 1.0 + 1.0 * d.nanos() / kNanosPerSecond) * r;
   int64 seconds = static_cast<int64>(result);
   int32 nanos = static_cast<int32>((result - seconds) * kNanosPerSecond);
   // Note that we normalize here not just because nanos can have a different
   // sign from seconds but also that nanos can be any arbitrary value when
   // overflow happens (i.e., the result is a much larger value than what
   // int64 can represent).
   d = CreateNormalized<Duration>(seconds, nanos);
   return d;
 }

 Duration& operator/=(Duration& d, int64 r) {  // NOLINT
   bool negative;
   uint128 value;
   ToUint128(d, &value, &negative);
   if (r > 0) {
     value /= static_cast<uint64>(r);
   } else {
     negative = !negative;
     value /= static_cast<uint64>(-r);
   }
   ToDuration(value, negative, &d);
   return d;
 }

 Duration& operator/=(Duration& d, double r) {  // NOLINT
   return d *= 1.0 / r;
 }

 Duration& operator%=(Duration& d1, const Duration& d2) {  // NOLINT
   bool negative1, negative2;
   uint128 value1, value2;
   ToUint128(d1, &value1, &negative1);
   ToUint128(d2, &value2, &negative2);
   uint128 result = value1 % value2;
   // When negative values are involved in division, we round the division
   // result towards zero. With this semantics, sign of the remainder is the
   // same as the dividend. For example:
   //     -5 / 10    = 0, -5 % 10    = -5
   //     -5 / (-10) = 0, -5 % (-10) = -5
   //      5 / (-10) = 0,  5 % (-10) = 5
   ToDuration(result, negative1, &d1);
   return d1;
 }

 int64 operator/(const Duration& d1, const Duration& d2) {
   bool negative1, negative2;
   uint128 value1, value2;
   ToUint128(d1, &value1, &negative1);
   ToUint128(d2, &value2, &negative2);
   int64 result = Uint128Low64(value1 / value2);
   if (negative1 != negative2) {
     result = -result;
   }
   return result;
 }

 Timestamp& operator+=(Timestamp& t, const Duration& d) {  // NOLINT
   t = CreateNormalized<Timestamp>(t.seconds() + d.seconds(),
                                   t.nanos() + d.nanos());
   return t;
 }

 Timestamp& operator-=(Timestamp& t, const Duration& d) {  // NOLINT
   t = CreateNormalized<Timestamp>(t.seconds() - d.seconds(),
                                   t.nanos() - d.nanos());
   return t;
 }

 Duration operator-(const Timestamp& t1, const Timestamp& t2) {
   return CreateNormalized<Duration>(t1.seconds() - t2.seconds(),
                                     t1.nanos() - t2.nanos());
 }
 }  // namespace protobuf

 }  // namespace google
	// Protocol Buffers - Google's data interchange format
	// Copyright 2008 Google Inc. All rights reserved.
	// https://developers.google.com/protocol-buffers/
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following disclaimer
	// in the documentation and/or other materials provided with the
	// distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#include <google/protobuf/util/time_util.h>

	#include <google/protobuf/stubs/time.h>
	#include <google/protobuf/stubs/int128.h>
	#include <google/protobuf/stubs/strutil.h>
	#include <google/protobuf/stubs/stringprintf.h>
	#include <google/protobuf/duration.pb.h>
	#include <google/protobuf/timestamp.pb.h>

	namespace google {
	namespace protobuf {
	namespace util {

	using google::protobuf::Timestamp;
	using google::protobuf::Duration;

	namespace {
	static const int kNanosPerSecond = 1000000000;
	static const int kMicrosPerSecond = 1000000;
	static const int kMillisPerSecond = 1000;
	static const int kNanosPerMillisecond = 1000000;
	static const int kMicrosPerMillisecond = 1000;
	static const int kNanosPerMicrosecond = 1000;
	static const int kSecondsPerMinute = 60; // Note that we ignore leap seconds.
	static const int kSecondsPerHour = 3600;
	static const char kTimestampFormat[] = "%E4Y-%m-%dT%H:%M:%S";

	template <typename T>
	T CreateNormalized(int64 seconds, int64 nanos);

	template <>
	Timestamp CreateNormalized(int64 seconds, int64 nanos) {
	// Make sure nanos is in the range.
	if (nanos <= -kNanosPerSecond \|\| nanos >= kNanosPerSecond) {
	seconds += nanos / kNanosPerSecond;
	nanos = nanos % kNanosPerSecond;
	}
	// For Timestamp nanos should be in the range [0, 999999999]
	if (nanos < 0) {
	seconds -= 1;
	nanos += kNanosPerSecond;
	}
	GOOGLE_DCHECK(seconds >= TimeUtil::kTimestampMinSeconds &&
	seconds <= TimeUtil::kTimestampMaxSeconds);
	Timestamp result;
	result.set_seconds(seconds);
	result.set_nanos(static_cast<int32>(nanos));
	return result;
	}

	template <>
	Duration CreateNormalized(int64 seconds, int64 nanos) {
	// Make sure nanos is in the range.
	if (nanos <= -kNanosPerSecond \|\| nanos >= kNanosPerSecond) {
	seconds += nanos / kNanosPerSecond;
	nanos = nanos % kNanosPerSecond;
	}
	// nanos should have the same sign as seconds.
	if (seconds < 0 && nanos > 0) {
	seconds += 1;
	nanos -= kNanosPerSecond;
	} else if (seconds > 0 && nanos < 0) {
	seconds -= 1;
	nanos += kNanosPerSecond;
	}
	GOOGLE_DCHECK(seconds >= TimeUtil::kDurationMinSeconds &&
	seconds <= TimeUtil::kDurationMaxSeconds);
	Duration result;
	result.set_seconds(seconds);
	result.set_nanos(static_cast<int32>(nanos));
	return result;
	}

	// Format nanoseconds with either 3, 6, or 9 digits depending on the required
	// precision to represent the exact value.
	string FormatNanos(int32 nanos) {
	if (nanos % kNanosPerMillisecond == 0) {
	return StringPrintf("%03d", nanos / kNanosPerMillisecond);
	} else if (nanos % kNanosPerMicrosecond == 0) {
	return StringPrintf("%06d", nanos / kNanosPerMicrosecond);
	} else {
	return StringPrintf("%09d", nanos);
	}
	}

	string FormatTime(int64 seconds, int32 nanos) {
	return ::google::protobuf::internal::FormatTime(seconds, nanos);
	}

	bool ParseTime(const string& value, int64* seconds, int32* nanos) {
	return ::google::protobuf::internal::ParseTime(value, seconds, nanos);
	}

	void CurrentTime(int64* seconds, int32* nanos) {
	return ::google::protobuf::internal::GetCurrentTime(seconds, nanos);
	}

	// Truncates the remainder part after division.
	int64 RoundTowardZero(int64 value, int64 divider) {
	int64 result = value / divider;
	int64 remainder = value % divider;
	// Before C++11, the sign of the remainder is implementation dependent if
	// any of the operands is negative. Here we try to enforce C++11's "rounded
	// toward zero" semantics. For example, for (-5) / 2 an implementation may
	// give -3 as the result with the remainder being 1. This function ensures
	// we always return -2 (closer to zero) regardless of the implementation.
	if (result < 0 && remainder > 0) {
	return result + 1;
	} else {
	return result;
	}
	}
	} // namespace

	string TimeUtil::ToString(const Timestamp& timestamp) {
	return FormatTime(timestamp.seconds(), timestamp.nanos());
	}

	bool TimeUtil::FromString(const string& value, Timestamp* timestamp) {
	int64 seconds;
	int32 nanos;
	if (!ParseTime(value, &seconds, &nanos)) {
	return false;
	}
	*timestamp = CreateNormalized<Timestamp>(seconds, nanos);
	return true;
	}

	Timestamp TimeUtil::GetCurrentTime() {
	int64 seconds;
	int32 nanos;
	CurrentTime(&seconds, &nanos);
	return CreateNormalized<Timestamp>(seconds, nanos);
	}

	Timestamp TimeUtil::GetEpoch() { return Timestamp(); }

	string TimeUtil::ToString(const Duration& duration) {
	string result;
	int64 seconds = duration.seconds();
	int32 nanos = duration.nanos();
	if (seconds < 0 \|\| nanos < 0) {
	result += "-";
	seconds = -seconds;
	nanos = -nanos;
	}
	result += StringPrintf("%" GOOGLE_LL_FORMAT "d", seconds);
	if (nanos != 0) {
	result += "." + FormatNanos(nanos);
	}
	result += "s";
	return result;
	}

	static int64 Pow(int64 x, int y) {
	int64 result = 1;
	for (int i = 0; i < y; ++i) {
	result *= x;
	}
	return result;
	}

	bool TimeUtil::FromString(const string& value, Duration* duration) {
	if (value.length() <= 1 \|\| value[value.length() - 1] != 's') {
	return false;
	}
	bool negative = (value[0] == '-');
	int sign_length = (negative ? 1 : 0);
	// Parse the duration value as two integers rather than a float value
	// to avoid precision loss.
	string seconds_part, nanos_part;
	size_t pos = value.find_last_of(".");
	if (pos == string::npos) {
	seconds_part = value.substr(sign_length, value.length() - 1 - sign_length);
	nanos_part = "0";
	} else {
	seconds_part = value.substr(sign_length, pos - sign_length);
	nanos_part = value.substr(pos + 1, value.length() - pos - 2);
	}
	char* end;
	int64 seconds = strto64(seconds_part.c_str(), &end, 10);
	if (end != seconds_part.c_str() + seconds_part.length()) {
	return false;
	}
	int64 nanos = strto64(nanos_part.c_str(), &end, 10);
	if (end != nanos_part.c_str() + nanos_part.length()) {
	return false;
	}
	nanos = nanos * Pow(10, 9 - nanos_part.length());
	if (negative) {
	// If a Duration is negative, both seconds and nanos should be negative.
	seconds = -seconds;
	nanos = -nanos;
	}
	duration->set_seconds(seconds);
	duration->set_nanos(static_cast<int32>(nanos));
	return true;
	}

	Duration TimeUtil::NanosecondsToDuration(int64 nanos) {
	return CreateNormalized<Duration>(nanos / kNanosPerSecond,
	nanos % kNanosPerSecond);
	}

	Duration TimeUtil::MicrosecondsToDuration(int64 micros) {
	return CreateNormalized<Duration>(
	micros / kMicrosPerSecond,
	(micros % kMicrosPerSecond) * kNanosPerMicrosecond);
	}

	Duration TimeUtil::MillisecondsToDuration(int64 millis) {
	return CreateNormalized<Duration>(
	millis / kMillisPerSecond,
	(millis % kMillisPerSecond) * kNanosPerMillisecond);
	}

	Duration TimeUtil::SecondsToDuration(int64 seconds) {
	return CreateNormalized<Duration>(seconds, 0);
	}

	Duration TimeUtil::MinutesToDuration(int64 minutes) {
	return CreateNormalized<Duration>(minutes * kSecondsPerMinute, 0);
	}

	Duration TimeUtil::HoursToDuration(int64 hours) {
	return CreateNormalized<Duration>(hours * kSecondsPerHour, 0);
	}

	int64 TimeUtil::DurationToNanoseconds(const Duration& duration) {
	return duration.seconds() * kNanosPerSecond + duration.nanos();
	}

	int64 TimeUtil::DurationToMicroseconds(const Duration& duration) {
	return duration.seconds() * kMicrosPerSecond +
	RoundTowardZero(duration.nanos(), kNanosPerMicrosecond);
	}

	int64 TimeUtil::DurationToMilliseconds(const Duration& duration) {
	return duration.seconds() * kMillisPerSecond +
	RoundTowardZero(duration.nanos(), kNanosPerMillisecond);
	}

	int64 TimeUtil::DurationToSeconds(const Duration& duration) {
	return duration.seconds();
	}

	int64 TimeUtil::DurationToMinutes(const Duration& duration) {
	return RoundTowardZero(duration.seconds(), kSecondsPerMinute);
	}

	int64 TimeUtil::DurationToHours(const Duration& duration) {
	return RoundTowardZero(duration.seconds(), kSecondsPerHour);
	}

	Timestamp TimeUtil::NanosecondsToTimestamp(int64 nanos) {
	return CreateNormalized<Timestamp>(nanos / kNanosPerSecond,
	nanos % kNanosPerSecond);
	}

	Timestamp TimeUtil::MicrosecondsToTimestamp(int64 micros) {
	return CreateNormalized<Timestamp>(
	micros / kMicrosPerSecond,
	micros % kMicrosPerSecond * kNanosPerMicrosecond);
	}

	Timestamp TimeUtil::MillisecondsToTimestamp(int64 millis) {
	return CreateNormalized<Timestamp>(
	millis / kMillisPerSecond,
	millis % kMillisPerSecond * kNanosPerMillisecond);
	}

	Timestamp TimeUtil::SecondsToTimestamp(int64 seconds) {
	return CreateNormalized<Timestamp>(seconds, 0);
	}

	int64 TimeUtil::TimestampToNanoseconds(const Timestamp& timestamp) {
	return timestamp.seconds() * kNanosPerSecond + timestamp.nanos();
	}

	int64 TimeUtil::TimestampToMicroseconds(const Timestamp& timestamp) {
	return timestamp.seconds() * kMicrosPerSecond +
	RoundTowardZero(timestamp.nanos(), kNanosPerMicrosecond);
	}

	int64 TimeUtil::TimestampToMilliseconds(const Timestamp& timestamp) {
	return timestamp.seconds() * kMillisPerSecond +
	RoundTowardZero(timestamp.nanos(), kNanosPerMillisecond);
	}

	int64 TimeUtil::TimestampToSeconds(const Timestamp& timestamp) {
	return timestamp.seconds();
	}

	Timestamp TimeUtil::TimeTToTimestamp(time_t value) {
	return CreateNormalized<Timestamp>(static_cast<int64>(value), 0);
	}

	time_t TimeUtil::TimestampToTimeT(const Timestamp& value) {
	return static_cast<time_t>(value.seconds());
	}

	Timestamp TimeUtil::TimevalToTimestamp(const timeval& value) {
	return CreateNormalized<Timestamp>(value.tv_sec,
	value.tv_usec * kNanosPerMicrosecond);
	}

	timeval TimeUtil::TimestampToTimeval(const Timestamp& value) {
	timeval result;
	result.tv_sec = value.seconds();
	result.tv_usec = RoundTowardZero(value.nanos(), kNanosPerMicrosecond);
	return result;
	}

	Duration TimeUtil::TimevalToDuration(const timeval& value) {
	return CreateNormalized<Duration>(value.tv_sec,
	value.tv_usec * kNanosPerMicrosecond);
	}

	timeval TimeUtil::DurationToTimeval(const Duration& value) {
	timeval result;
	result.tv_sec = value.seconds();
	result.tv_usec = RoundTowardZero(value.nanos(), kNanosPerMicrosecond);
	// timeval.tv_usec's range is [0, 1000000)
	if (result.tv_usec < 0) {
	result.tv_sec -= 1;
	result.tv_usec += kMicrosPerSecond;
	}
	return result;
	}

	} // namespace util
	} // namespace protobuf


	namespace protobuf {
	namespace {
	using google::protobuf::util::kNanosPerSecond;
	using google::protobuf::util::CreateNormalized;

	// Convert a Timestamp to uint128.
	void ToUint128(const Timestamp& value, uint128* result, bool* negative) {
	if (value.seconds() < 0) {
	*negative = true;
	*result = static_cast<uint64>(-value.seconds());
	result = result * kNanosPerSecond - static_cast<uint32>(value.nanos());
	} else {
	*negative = false;
	*result = static_cast<uint64>(value.seconds());
	result = result * kNanosPerSecond + static_cast<uint32>(value.nanos());
	}
	}

	// Convert a Duration to uint128.
	void ToUint128(const Duration& value, uint128* result, bool* negative) {
	if (value.seconds() < 0 \|\| value.nanos() < 0) {
	*negative = true;
	*result = static_cast<uint64>(-value.seconds());
	result = result * kNanosPerSecond + static_cast<uint32>(-value.nanos());
	} else {
	*negative = false;
	*result = static_cast<uint64>(value.seconds());
	result = result * kNanosPerSecond + static_cast<uint32>(value.nanos());
	}
	}

	void ToTimestamp(const uint128& value, bool negative, Timestamp* timestamp) {
	int64 seconds = static_cast<int64>(Uint128Low64(value / kNanosPerSecond));
	int32 nanos = static_cast<int32>(Uint128Low64(value % kNanosPerSecond));
	if (negative) {
	seconds = -seconds;
	nanos = -nanos;
	if (nanos < 0) {
	nanos += kNanosPerSecond;
	seconds -= 1;
	}
	}
	timestamp->set_seconds(seconds);
	timestamp->set_nanos(nanos);
	}

	void ToDuration(const uint128& value, bool negative, Duration* duration) {
	int64 seconds = static_cast<int64>(Uint128Low64(value / kNanosPerSecond));
	int32 nanos = static_cast<int32>(Uint128Low64(value % kNanosPerSecond));
	if (negative) {
	seconds = -seconds;
	nanos = -nanos;
	}
	duration->set_seconds(seconds);
	duration->set_nanos(nanos);
	}
	} // namespace

	Duration& operator+=(Duration& d1, const Duration& d2) {
	d1 = CreateNormalized<Duration>(d1.seconds() + d2.seconds(),
	d1.nanos() + d2.nanos());
	return d1;
	}

	Duration& operator-=(Duration& d1, const Duration& d2) { // NOLINT
	d1 = CreateNormalized<Duration>(d1.seconds() - d2.seconds(),
	d1.nanos() - d2.nanos());
	return d1;
	}

	Duration& operator*=(Duration& d, int64 r) { // NOLINT
	bool negative;
	uint128 value;
	ToUint128(d, &value, &negative);
	if (r > 0) {
	value *= static_cast<uint64>(r);
	} else {
	negative = !negative;
	value *= static_cast<uint64>(-r);
	}
	ToDuration(value, negative, &d);
	return d;
	}

	Duration& operator*=(Duration& d, double r) { // NOLINT
	double result = (d.seconds() * 1.0 + 1.0 * d.nanos() / kNanosPerSecond) * r;
	int64 seconds = static_cast<int64>(result);
	int32 nanos = static_cast<int32>((result - seconds) * kNanosPerSecond);
	// Note that we normalize here not just because nanos can have a different
	// sign from seconds but also that nanos can be any arbitrary value when
	// overflow happens (i.e., the result is a much larger value than what
	// int64 can represent).
	d = CreateNormalized<Duration>(seconds, nanos);
	return d;
	}

	Duration& operator/=(Duration& d, int64 r) { // NOLINT
	bool negative;
	uint128 value;
	ToUint128(d, &value, &negative);
	if (r > 0) {
	value /= static_cast<uint64>(r);
	} else {
	negative = !negative;
	value /= static_cast<uint64>(-r);
	}
	ToDuration(value, negative, &d);
	return d;
	}

	Duration& operator/=(Duration& d, double r) { // NOLINT
	return d *= 1.0 / r;
	}

	Duration& operator%=(Duration& d1, const Duration& d2) { // NOLINT
	bool negative1, negative2;
	uint128 value1, value2;
	ToUint128(d1, &value1, &negative1);
	ToUint128(d2, &value2, &negative2);
	uint128 result = value1 % value2;
	// When negative values are involved in division, we round the division
	// result towards zero. With this semantics, sign of the remainder is the
	// same as the dividend. For example:
	// -5 / 10 = 0, -5 % 10 = -5
	// -5 / (-10) = 0, -5 % (-10) = -5
	// 5 / (-10) = 0, 5 % (-10) = 5
	ToDuration(result, negative1, &d1);
	return d1;
	}

	int64 operator/(const Duration& d1, const Duration& d2) {
	bool negative1, negative2;
	uint128 value1, value2;
	ToUint128(d1, &value1, &negative1);
	ToUint128(d2, &value2, &negative2);
	int64 result = Uint128Low64(value1 / value2);
	if (negative1 != negative2) {
	result = -result;
	}
	return result;
	}

	Timestamp& operator+=(Timestamp& t, const Duration& d) { // NOLINT
	t = CreateNormalized<Timestamp>(t.seconds() + d.seconds(),
	t.nanos() + d.nanos());
	return t;
	}

	Timestamp& operator-=(Timestamp& t, const Duration& d) { // NOLINT
	t = CreateNormalized<Timestamp>(t.seconds() - d.seconds(),
	t.nanos() - d.nanos());
	return t;
	}

	Duration operator-(const Timestamp& t1, const Timestamp& t2) {
	return CreateNormalized<Duration>(t1.seconds() - t2.seconds(),
	t1.nanos() - t2.nanos());
	}
	} // namespace protobuf

	} // namespace google