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/*
*
* Copyright (c) 2020 Project CHIP Authors
* Copyright (c) 2018 Nest Labs, Inc.
*
* 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
*
* http://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
* This is an internal header file that defines the interface to a platform-supplied
* function for retrieving the current system time.
*/
#pragma once
// Include configuration headers
#include <system/SystemConfig.h>
// Include dependent headers
#include <lib/support/DLLUtil.h>
#include <lib/support/TimeUtils.h>
#include <system/SystemError.h>
#if CHIP_SYSTEM_CONFIG_USE_POSIX_TIME_FUNCTS || CHIP_SYSTEM_CONFIG_USE_POSIX_SOCKETS
#include <sys/time.h>
#endif // CHIP_SYSTEM_CONFIG_USE_POSIX_TIME_FUNCTS || CHIP_SYSTEM_CONFIG_USE_POSIX_SOCKETS
#if CHIP_SYSTEM_CONFIG_USE_ZEPHYR_SOCKETS
#include <zephyr/net/socket.h>
#endif
#include <chrono>
#include <stdint.h>
namespace chip {
namespace System {
namespace Clock {
/*
* We use `std::chrono::duration` for clock types to provide type safety. But unlike the predefined std types
* (`std::chrono::milliseconds` et al), CHIP uses unsigned base types, and types are explicity sized, with
* smaller-size types available for members and arguments where appropriate.
*
* Most conversions are handled by the types transparently. To convert with possible loss of information, use
* `std::chrono::duration_cast<>()`.
*/
using Microseconds64 = std::chrono::duration<uint64_t, std::micro>;
using Microseconds32 = std::chrono::duration<uint32_t, std::micro>;
using Milliseconds64 = std::chrono::duration<uint64_t, std::milli>;
using Milliseconds32 = std::chrono::duration<uint32_t, std::milli>;
using Seconds64 = std::chrono::duration<uint64_t>;
using Seconds32 = std::chrono::duration<uint32_t>;
using Seconds16 = std::chrono::duration<uint16_t>;
constexpr Seconds16 kZero{ 0 };
namespace Literals {
constexpr Microseconds64 operator""_us(unsigned long long int us)
{
return Microseconds64(us);
}
constexpr Microseconds64 operator""_us64(unsigned long long int us)
{
return Microseconds64(us);
}
constexpr Microseconds32 operator""_us32(unsigned long long int us)
{
return Microseconds32(us);
}
constexpr Milliseconds64 operator""_ms(unsigned long long int ms)
{
return Milliseconds64(ms);
}
constexpr Milliseconds64 operator""_ms64(unsigned long long int ms)
{
return Milliseconds64(ms);
}
constexpr Milliseconds32 operator""_ms32(unsigned long long int ms)
{
return Milliseconds32(ms);
}
constexpr Seconds64 operator""_s(unsigned long long int s)
{
return Seconds64(s);
}
constexpr Seconds64 operator""_s64(unsigned long long int s)
{
return Seconds64(s);
}
constexpr Seconds32 operator""_s32(unsigned long long int s)
{
return Seconds32(s);
}
constexpr Seconds16 operator""_s16(unsigned long long int s)
{
return Seconds16(s);
}
} // namespace Literals
/**
* Type for System time stamps.
*/
using Timestamp = Milliseconds64;
/**
* Type for System time offsets (i.e. `StartTime()` duration).
*
* It is required of platforms that time stamps from `GetMonotonic…()` have the high bit(s) zero,
* so the sum of a `Milliseconds64` time stamp and `Milliseconds32` offset will never overflow.
*/
using Timeout = Milliseconds32;
class ClockBase
{
public:
virtual ~ClockBase() = default;
/**
* Returns a monotonic system time.
*
* This function returns an elapsed time since an arbitrary, platform-defined epoch.
* The value returned is guaranteed to be ever-increasing (i.e. never wrapping or decreasing) between
* reboots of the system. Additionally, the underlying time source is guaranteed to tick
* continuously during any system sleep modes that do not entail a restart upon wake.
*
* Although some platforms may choose to return a value that measures the time since boot for the
* system, applications must *not* rely on this.
*/
Timestamp GetMonotonicTimestamp() { return GetMonotonicMilliseconds64(); }
/**
* Returns a monotonic system time in units of microseconds.
*
* This function returns an elapsed time in microseconds since an arbitrary, platform-defined epoch.
* The value returned is guaranteed to be ever-increasing (i.e. never wrapping or decreasing) between
* reboots of the system. Additionally, the underlying time source is guaranteed to tick
* continuously during any system sleep modes that do not entail a restart upon wake.
*
* Although some platforms may choose to return a value that measures the time since boot for the
* system, applications must *not* rely on this.
*
* Applications must not rely on the time returned by GetMonotonicMicroseconds64() actually having
* granularity finer than milliseconds.
*
* Platform implementations *must* use the same epoch for GetMonotonicMicroseconds64() and GetMonotonicMilliseconds64().
*
* Platforms *must* use an epoch such that the upper bit of a value returned by GetMonotonicMicroseconds64() is zero
* for the expected operational life of the system.
*
* @returns Elapsed time in microseconds since an arbitrary, platform-defined epoch.
*/
virtual Microseconds64 GetMonotonicMicroseconds64() = 0;
/**
* Returns a monotonic system time in units of milliseconds.
*
* This function returns an elapsed time in milliseconds since an arbitrary, platform-defined epoch.
* The value returned is guaranteed to be ever-increasing (i.e. never wrapping or decreasing) between
* reboots of the system. Additionally, the underlying time source is guaranteed to tick
* continuously during any system sleep modes that do not entail a restart upon wake.
*
* Although some platforms may choose to return a value that measures the time since boot for the
* system, applications must *not* rely on this.
*
* Platform implementations *must* use the same epoch for GetMonotonicMicroseconds64() and GetMonotonicMilliseconds64().
* (As a consequence of this, and the requirement for GetMonotonicMicroseconds64() to return high bit zero, values
* returned by GetMonotonicMilliseconds64() will have the high ten bits zero.)
*
* @returns Elapsed time in milliseconds since an arbitrary, platform-defined epoch.
*/
virtual Milliseconds64 GetMonotonicMilliseconds64() = 0;
/**
* @brief
* Platform-specific function for getting the current real (civil) time in microsecond Unix time
* format.
*
* This function is expected to return the local platform's notion of current real time, expressed
* as a Unix time value scaled to microseconds. The underlying clock is required to tick at a
* rate of least at whole seconds (values of 1,000,000), but may tick faster.
*
* On those platforms that are capable of tracking real time, GetClock_RealTime() must return the
* error CHIP_ERROR_REAL_TIME_NOT_SYNCED whenever the system is unsynchronized with real time.
*
* Platforms that are incapable of tracking real time should not implement the GetClock_RealTime()
* function, thereby forcing link-time failures of features that depend on access to real time.
* Alternatively, such platforms may supply an implementation of GetClock_RealTime() that returns
* the error CHIP_ERROR_UNSUPPORTED_CHIP_FEATURE.
*
* This function is expected to be thread-safe on any platform that employs threading.
*
* @note
* This function is reserved for internal use by the System Clock. Users of the System
* Clock should call System::Clock::GetClock_RealTime().
*
* @param[out] aCurTime The current time, expressed as Unix time scaled to microseconds.
*
* @retval #CHIP_NO_ERROR If the method succeeded.
* @retval #CHIP_ERROR_REAL_TIME_NOT_SYNCED
* If the platform is capable of tracking real time, but is
* is currently unsynchronized.
* @retval #CHIP_ERROR_UNSUPPORTED_CHIP_FEATURE
* If the platform is incapable of tracking real time.
*/
virtual CHIP_ERROR GetClock_RealTime(Microseconds64 & aCurTime) = 0;
/**
* @brief
* Platform-specific function for getting the current real (civil) time in millisecond Unix time
* format.
*
* This function is expected to return the local platform's notion of current real time, expressed
* as a Unix time value scaled to milliseconds.
*
* See the documentation for GetClock_RealTime() for details on the expected behavior.
*
* @note
* This function is reserved for internal use by the System Clock. Users of the System
* Clock should call System::Clock::GetClock_RealTimeMS().
*
* @param[out] aCurTime The current time, expressed as Unix time scaled to milliseconds.
*
* @retval #CHIP_NO_ERROR If the method succeeded.
* @retval #CHIP_ERROR_REAL_TIME_NOT_SYNCED
* If the platform is capable of tracking real time, but is
* is currently unsynchronized.
* @retval #CHIP_ERROR_UNSUPPORTED_CHIP_FEATURE
* If the platform is incapable of tracking real time.
*/
virtual CHIP_ERROR GetClock_RealTimeMS(Milliseconds64 & aCurTime) = 0;
/**
* @brief
* Platform-specific function for setting the current real (civil) time.
*
* This function set the local platform's notion of current real time. The new current
* time is expressed as a Unix time value scaled to microseconds.
*
* Once set, underlying platform clock is expected to track real time with a granularity of at least whole
* seconds.
*
* On platforms that support tracking real time, the SetClock_RealTime() function must return the error
* CHIP_ERROR_ACCESS_DENIED if the calling application does not have the privilege to set the
* current time.
*
* Platforms that are incapable of tracking real time, or do not offer the ability to set real time,
* should not implement the SetClock_RealTime() function, thereby forcing link-time failures of features
* that depend on setting real time. Alternatively, such platforms may supply an implementation of
* SetClock_RealTime() that returns the error CHIP_ERROR_UNSUPPORTED_CHIP_FEATURE.
*
* This function is expected to be thread-safe on any platform that employs threading.
*
* @note
* This function is reserved for internal use by the System Clock. Users of the System
* Clock should call System::Clock::GetClock_RealTimeMS().
*
* @param[in] aNewCurTime The new current time, expressed as Unix time scaled to microseconds.
*
* @retval #CHIP_NO_ERROR If the method succeeded.
* @retval #CHIP_ERROR_UNSUPPORTED_CHIP_FEATURE
* If the platform is incapable of tracking real time.
* @retval #CHIP_ERROR_ACCESS_DENIED
* If the calling application does not have the privilege to set the
* current time.
*/
virtual CHIP_ERROR SetClock_RealTime(Microseconds64 aNewCurTime) = 0;
};
// Currently we have a single implementation class, ClockImpl, whose members are implemented in build-specific files.
class ClockImpl : public ClockBase
{
public:
~ClockImpl() override = default;
Microseconds64 GetMonotonicMicroseconds64() override;
Milliseconds64 GetMonotonicMilliseconds64() override;
CHIP_ERROR GetClock_RealTime(Microseconds64 & aCurTime) override;
CHIP_ERROR GetClock_RealTimeMS(Milliseconds64 & aCurTime) override;
CHIP_ERROR SetClock_RealTime(Microseconds64 aNewCurTime) override;
};
namespace Internal {
// This should only be used via SystemClock() below.
extern ClockBase * gClockBase;
inline void SetSystemClockForTesting(Clock::ClockBase * clock)
{
Clock::Internal::gClockBase = clock;
}
// Provide a mock implementation for use by unit tests.
class MockClock : public ClockImpl
{
public:
Microseconds64 GetMonotonicMicroseconds64() override { return mSystemTime; }
Milliseconds64 GetMonotonicMilliseconds64() override { return std::chrono::duration_cast<Milliseconds64>(mSystemTime); }
CHIP_ERROR GetClock_RealTime(Microseconds64 & aCurTime) override
{
aCurTime = mRealTime;
return CHIP_NO_ERROR;
}
CHIP_ERROR GetClock_RealTimeMS(Milliseconds64 & aCurTime) override
{
aCurTime = std::chrono::duration_cast<Milliseconds64>(mRealTime);
return CHIP_NO_ERROR;
}
CHIP_ERROR SetClock_RealTime(Microseconds64 aNewCurTime) override
{
mRealTime = aNewCurTime;
return CHIP_NO_ERROR;
}
void SetMonotonic(Milliseconds64 timestamp) { mSystemTime = timestamp; }
void AdvanceMonotonic(Milliseconds64 increment) { mSystemTime += increment; }
void AdvanceRealTime(Milliseconds64 increment) { mRealTime += increment; }
Microseconds64 mSystemTime = Clock::kZero;
Microseconds64 mRealTime = Clock::kZero;
};
} // namespace Internal
#if CHIP_SYSTEM_CONFIG_USE_POSIX_TIME_FUNCTS || CHIP_SYSTEM_CONFIG_USE_SOCKETS
Microseconds64 TimevalToMicroseconds(const timeval & in);
void ToTimeval(Microseconds64 in, timeval & out);
#endif // CHIP_SYSTEM_CONFIG_USE_POSIX_TIME_FUNCTS || CHIP_SYSTEM_CONFIG_USE_SOCKETS
} // namespace Clock
inline Clock::ClockBase & SystemClock()
{
return *Clock::Internal::gClockBase;
}
} // namespace System
} // namespace chip