/* * Copyright (c) 2018 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #ifndef API_UNITS_TIMESTAMP_H_ #define API_UNITS_TIMESTAMP_H_ #include #include #include #include "api/units/time_delta.h" #include "rtc_base/checks.h" #include "rtc_base/units/unit_base.h" // IWYU pragma: export namespace webrtc { // Timestamp represents the time that has passed since some unspecified epoch. // The epoch is assumed to be before any represented timestamps, this means that // negative values are not valid. The most notable feature is that the // difference of two Timestamps results in a TimeDelta. class Timestamp final : public rtc_units_impl::UnitBase { public: template static constexpr Timestamp Seconds(T value) { static_assert(std::is_arithmetic::value, ""); return FromFraction(1'000'000, value); } template static constexpr Timestamp Millis(T value) { static_assert(std::is_arithmetic::value, ""); return FromFraction(1'000, value); } template static constexpr Timestamp Micros(T value) { static_assert(std::is_arithmetic::value, ""); return FromValue(value); } Timestamp() = delete; template constexpr T seconds() const { return ToFraction<1000000, T>(); } template constexpr T ms() const { return ToFraction<1000, T>(); } template constexpr T us() const { return ToValue(); } constexpr int64_t seconds_or(int64_t fallback_value) const { return ToFractionOr<1000000>(fallback_value); } constexpr int64_t ms_or(int64_t fallback_value) const { return ToFractionOr<1000>(fallback_value); } constexpr int64_t us_or(int64_t fallback_value) const { return ToValueOr(fallback_value); } constexpr Timestamp operator+(const TimeDelta delta) const { if (IsPlusInfinity() || delta.IsPlusInfinity()) { RTC_DCHECK(!IsMinusInfinity()); RTC_DCHECK(!delta.IsMinusInfinity()); return PlusInfinity(); } else if (IsMinusInfinity() || delta.IsMinusInfinity()) { RTC_DCHECK(!IsPlusInfinity()); RTC_DCHECK(!delta.IsPlusInfinity()); return MinusInfinity(); } return Timestamp::Micros(us() + delta.us()); } constexpr Timestamp operator-(const TimeDelta delta) const { if (IsPlusInfinity() || delta.IsMinusInfinity()) { RTC_DCHECK(!IsMinusInfinity()); RTC_DCHECK(!delta.IsPlusInfinity()); return PlusInfinity(); } else if (IsMinusInfinity() || delta.IsPlusInfinity()) { RTC_DCHECK(!IsPlusInfinity()); RTC_DCHECK(!delta.IsMinusInfinity()); return MinusInfinity(); } return Timestamp::Micros(us() - delta.us()); } constexpr TimeDelta operator-(const Timestamp other) const { if (IsPlusInfinity() || other.IsMinusInfinity()) { RTC_DCHECK(!IsMinusInfinity()); RTC_DCHECK(!other.IsPlusInfinity()); return TimeDelta::PlusInfinity(); } else if (IsMinusInfinity() || other.IsPlusInfinity()) { RTC_DCHECK(!IsPlusInfinity()); RTC_DCHECK(!other.IsMinusInfinity()); return TimeDelta::MinusInfinity(); } return TimeDelta::Micros(us() - other.us()); } constexpr Timestamp& operator-=(const TimeDelta delta) { *this = *this - delta; return *this; } constexpr Timestamp& operator+=(const TimeDelta delta) { *this = *this + delta; return *this; } private: friend class rtc_units_impl::UnitBase; using UnitBase::UnitBase; static constexpr bool one_sided = true; }; std::string ToString(Timestamp value); inline std::string ToLogString(Timestamp value) { return ToString(value); } } // namespace webrtc #endif // API_UNITS_TIMESTAMP_H_