// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
//
// QuicTime represents one point in time, stored in microsecond resolution.
// QuicTime is monotonically increasing, even across system clock adjustments.
// The epoch (time 0) of QuicTime is unspecified.
//
// This implementation wraps the classes base::TimeTicks and base::TimeDelta.
#ifndef NET_QUIC_QUIC_TIME_H_
#define NET_QUIC_QUIC_TIME_H_
#include "base/basictypes.h"
#include "base/time/time.h"
#include "net/base/net_export.h"
namespace net {
static const uint64 kNumMicrosPerSecond = base::Time::kMicrosecondsPerSecond;
// A QuicTime is a purely relative time. QuicTime values from different clocks
// cannot be compared to each other. If you need an absolute time, see
// QuicWallTime, below.
class NET_EXPORT_PRIVATE QuicTime {
public:
// A QuicTime::Delta represents the signed difference between two points in
// time, stored in microsecond resolution.
class NET_EXPORT_PRIVATE Delta {
public:
explicit Delta(base::TimeDelta delta);
// Create a object with an offset of 0.
static Delta Zero();
// Create a object with infinite offset time.
static Delta Infinite();
// Converts a number of seconds to a time offset.
static Delta FromSeconds(int64 secs);
// Converts a number of milliseconds to a time offset.
static Delta FromMilliseconds(int64 ms);
// Converts a number of microseconds to a time offset.
static Delta FromMicroseconds(int64 us);
// Converts the time offset to a rounded number of seconds.
int64 ToSeconds() const;
// Converts the time offset to a rounded number of milliseconds.
int64 ToMilliseconds() const;
// Converts the time offset to a rounded number of microseconds.
int64 ToMicroseconds() const;
Delta Add(const Delta& delta) const;
Delta Subtract(const Delta& delta) const;
Delta Multiply(int i) const;
Delta Multiply(double d) const;
// Returns the later delta of time1 and time2.
static Delta Max(Delta delta1, Delta delta2);
bool IsZero() const;
bool IsInfinite() const;
private:
base::TimeDelta delta_;
friend class QuicTime;
friend class QuicClock;
};
explicit QuicTime(base::TimeTicks ticks);
// Creates a new QuicTime with an internal value of 0. IsInitialized()
// will return false for these times.
static QuicTime Zero();
// Returns the later time of time1 and time2.
static QuicTime Max(QuicTime time1, QuicTime time2);
// Produce the internal value to be used when logging. This value
// represents the number of microseconds since some epoch. It may
// be the UNIX epoch on some platforms. On others, it may
// be a CPU ticks based value.
int64 ToDebuggingValue() const;
bool IsInitialized() const;
QuicTime Add(const Delta& delta) const;
QuicTime Subtract(const Delta& delta) const;
Delta Subtract(const QuicTime& other) const;
private:
friend bool operator==(QuicTime lhs, QuicTime rhs);
friend bool operator<(QuicTime lhs, QuicTime rhs);
friend class QuicClock;
friend class QuicClockTest;
base::TimeTicks ticks_;
};
// A QuicWallTime represents an absolute time that is globally consistent. It
// provides, at most, one second granularity and, in practice, clock-skew means
// that you shouldn't even depend on that.
class NET_EXPORT_PRIVATE QuicWallTime {
public:
// FromUNIXSeconds constructs a QuicWallTime from a count of the seconds
// since the UNIX epoch.
static QuicWallTime FromUNIXSeconds(uint64 seconds);
// Zero returns a QuicWallTime set to zero. IsZero will return true for this
// value.
static QuicWallTime Zero();
// ToUNIXSeconds converts a QuicWallTime into a count of seconds since the
// UNIX epoch.
uint64 ToUNIXSeconds() const;
bool IsAfter(QuicWallTime other) const;
bool IsBefore(QuicWallTime other) const;
// IsZero returns true if this object is the result of calling |Zero|.
bool IsZero() const;
// AbsoluteDifference returns the absolute value of the time difference
// between |this| and |other|.
QuicTime::Delta AbsoluteDifference(QuicWallTime other) const;
// Add returns a new QuicWallTime that represents the time of |this| plus
// |delta|.
QuicWallTime Add(QuicTime::Delta delta) const;
// Subtract returns a new QuicWallTime that represents the time of |this|
// minus |delta|.
QuicWallTime Subtract(QuicTime::Delta delta) const;
private:
explicit QuicWallTime(uint64 seconds);
uint64 seconds_;
};
// Non-member relational operators for QuicTime::Delta.
inline bool operator==(QuicTime::Delta lhs, QuicTime::Delta rhs) {
return lhs.ToMicroseconds() == rhs.ToMicroseconds();
}
inline bool operator!=(QuicTime::Delta lhs, QuicTime::Delta rhs) {
return !(lhs == rhs);
}
inline bool operator<(QuicTime::Delta lhs, QuicTime::Delta rhs) {
return lhs.ToMicroseconds() < rhs.ToMicroseconds();
}
inline bool operator>(QuicTime::Delta lhs, QuicTime::Delta rhs) {
return rhs < lhs;
}
inline bool operator<=(QuicTime::Delta lhs, QuicTime::Delta rhs) {
return !(rhs < lhs);
}
inline bool operator>=(QuicTime::Delta lhs, QuicTime::Delta rhs) {
return !(lhs < rhs);
}
// Non-member relational operators for QuicTime.
inline bool operator==(QuicTime lhs, QuicTime rhs) {
return lhs.ticks_ == rhs.ticks_;
}
inline bool operator!=(QuicTime lhs, QuicTime rhs) {
return !(lhs == rhs);
}
inline bool operator<(QuicTime lhs, QuicTime rhs) {
return lhs.ticks_ < rhs.ticks_;
}
inline bool operator>(QuicTime lhs, QuicTime rhs) {
return rhs < lhs;
}
inline bool operator<=(QuicTime lhs, QuicTime rhs) {
return !(rhs < lhs);
}
inline bool operator>=(QuicTime lhs, QuicTime rhs) {
return !(lhs < rhs);
}
} // namespace net
#endif // NET_QUIC_QUIC_TIME_H_