pw_chrono/public/pw_chrono/system_clock.h - pigweed/pigweed - Git at Google

 // Copyright 2020 The Pigweed 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.
 #pragma once

 #include <stddef.h>
 #include <stdint.h>

 #include "pw_preprocessor/util.h"

 // The backend implements this header to provide the following SystemClock
 // parameters, for more detail on the parameters see the SystemClock usage of
 // them below:
 //   PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_NUMERATOR
 //   PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_DENOMINATOR
 //   constexpr pw::chrono::Epoch pw::chrono::backend::kSystemClockEpoch;
 //   constexpr bool pw::chrono::backend::kSystemClockFreeRunning;
 //   constexpr bool pw::chrono::backend::kSystemClockNmiSafe;
 #include "pw_chrono_backend/system_clock_config.h"

 #ifdef __cplusplus

 #include <chrono>
 #include <ratio>

 namespace pw::chrono {
 namespace backend {

 // The ARM AEBI does not permit the opaque 'time_point' to be passed via
 // registers, ergo the underlying fundamental type is forward declared.
 // A SystemCLock tick has the units of one SystemClock::period duration.
 // This must be thread and IRQ safe and provided by the backend.
 int64_t GetSystemClockTickCount();

 }  // namespace backend

 // The SystemClock represents an unsteady, monotonic clock.
 //
 // The epoch of this clock is unspecified and may not be related to wall time
 // (for example, it can be time since boot). The time between ticks of this
 // clock may vary due to sleep modes and potential interrupt handling.
 // SystemClock meets the requirements of C++'s TrivialClock and Pigweed's
 // PigweedClock.
 //
 // SystemClock is compatible with C++'s Clock & TrivialClock including:
 //   SystemClock::rep
 //   SystemClock::period
 //   SystemClock::duration
 //   SystemClock::time_point
 //   SystemClock::is_steady
 //   SystemClock::now()
 //
 // Example:
 //
 //   SystemClock::time_point before = SystemClock::now();
 //   TakesALongTime();
 //   SystemClock::duration time_taken = SystemClock::now() - before;
 //   bool took_way_too_long = false;
 //   if (time_taken > std::chrono::seconds(42)) {
 //     took_way_too_long = true;
 //   }
 //
 // This code is thread & IRQ safe, it may be NMI safe depending on is_nmi_safe.
 struct SystemClock {
   using rep = int64_t;
   // The period must be provided by the backend.
   using period = std::ratio<PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_NUMERATOR,
                             PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_DENOMINATOR>;
   using duration = std::chrono::duration<rep, period>;
   using time_point = std::chrono::time_point<SystemClock>;
   // The epoch must be provided by the backend.
   static constexpr Epoch epoch = backend::kSystemClockEpoch;

   // The time points of this clock cannot decrease, however the time between
   // ticks of this clock may slightly vary due to sleep modes. The duration
   // during sleep may be ignored or backfilled with another clock.
   static constexpr bool is_monotonic = true;
   static constexpr bool is_steady = false;

   // The now() function may not move forward while in a critical section or
   // interrupt. This must be provided by the backend.
   static constexpr bool is_free_running = backend::kSystemClockFreeRunning;

   // The clock must stop while in halting debug mode.
   static constexpr bool is_stopped_in_halting_debug_mode = true;

   // The now() function can be invoked at any time.
   static constexpr bool is_always_enabled = true;

   // The now() function may work in non-masking interrupts, depending on the
   // backend. This must be provided by the backend.
   static constexpr bool is_nmi_safe = backend::kSystemClockNmiSafe;

   // This is thread and IRQ safe. This must be provided by the backend.
   static time_point now() noexcept {
     return time_point(duration(backend::GetSystemClockTickCount()));
   }

   // This is purely a helper, identical to directly using std::chrono::ceil, to
   // convert a duration type which cannot be implicitly converted where the
   // result is rounded up.
   template <class Rep, class Period>
   static constexpr duration for_at_least(std::chrono::duration<Rep, Period> d) {
     return std::chrono::ceil<duration>(d);
   }

   // Computes the nearest time_point after the specified duration has elapsed.
   //
   // This is useful for translating delay or timeout durations into deadlines.
   //
   // The time_point is computed based on now() plus the specified duration
   // where a singular clock tick is added to handle partial ticks. This ensures
   // that a duration of at least 1 tick does not result in [0,1] ticks and
   // instead in [1,2] ticks.
   static time_point TimePointAfterAtLeast(duration after_at_least) {
     return now() + after_at_least + duration(1);
   }
 };

 // An abstract interface representing a SystemClock.
 //
 // This interface allows decoupling code that uses time from the code that
 // creates a point in time. You can use this to your advantage by injecting
 // Clocks into interfaces rather than having implementations call
 // SystemClock::now() directly. However, this comes at a cost of a vtable per
 // implementation and more importantly passing and maintaining references to the
 // VirtualSystemCLock for all of the users.
 //
 // The VirtualSystemClock::RealClock() function returns a reference to the
 // real global SystemClock.
 //
 // Example:
 //
 //  void DoFoo(VirtualSystemClock& system_clock) {
 //    SystemClock::time_point now = clock.now();
 //    // ... Code which consumes now.
 //  }
 //
 //  // Production code:
 //  DoFoo(VirtualSystemCLock::RealClock);
 //
 //  // Test code:
 //  MockClock test_clock();
 //  DoFoo(test_clock);
 //
 // This interface is thread and IRQ safe.
 class VirtualSystemClock {
  public:
   // Returns a reference to the real system clock to aid instantiation.
   static VirtualSystemClock& RealClock();

   virtual ~VirtualSystemClock() = default;
   virtual SystemClock::time_point now() = 0;
 };

 }  // namespace pw::chrono

 // The backend can opt to include an inlined implementation of the following:
 //   int64_t GetSystemClockTickCount();
 #if __has_include("pw_chrono_backend/system_clock_inline.h")
 #include "pw_chrono_backend/system_clock_inline.h"
 #endif  // __has_include("pw_chrono_backend/system_clock_inline.h")

 #endif  // __cplusplus

 PW_EXTERN_C_START

 // C API Users should not create pw_chrono_SystemClock_Duration's directly,
 // instead it is strongly recommended to use macros which express the duration
 // in time units, instead of non-portable ticks.
 //
 // The following macros round up just like std::chrono::ceil, this is the
 // recommended rounding to maintain the "at least" contract of timeouts and
 // deadlines (note the *_CEIL macros are the same only more explicit):
 //   PW_SYSTEM_CLOCK_MS(milliseconds)
 //   PW_SYSTEM_CLOCK_S(seconds)
 //   PW_SYSTEM_CLOCK_MIN(minutes)
 //   PW_SYSTEM_CLOCK_H(hours)
 //   PW_SYSTEM_CLOCK_MS_CEIL(milliseconds)
 //   PW_SYSTEM_CLOCK_S_CEIL(seconds)
 //   PW_SYSTEM_CLOCK_MIN_CEIL(minutes)
 //   PW_SYSTEM_CLOCK_H_CEIL(hours)
 //
 // The following macros round down like std::chrono::{floor,duration_cast},
 // these are discouraged but sometimes necessary:
 //   PW_SYSTEM_CLOCK_MS_FLOOR(milliseconds)
 //   PW_SYSTEM_CLOCK_S_FLOOR(seconds)
 //   PW_SYSTEM_CLOCK_MIN_FLOOR(minutes)
 //   PW_SYSTEM_CLOCK_H_FLOOR(hours)
 #include "pw_chrono/internal/system_clock_macros.h"

 typedef struct {
   int64_t ticks;
 } pw_chrono_SystemClock_Duration;

 typedef struct {
   pw_chrono_SystemClock_Duration duration_since_epoch;
 } pw_chrono_SystemClock_TimePoint;
 typedef int64_t pw_chrono_SystemClock_Nanoseconds;

 // Returns the current time, see SystemClock::now() for more detail.
 pw_chrono_SystemClock_TimePoint pw_chrono_SystemClock_Now(void);

 // Returns the change in time between the current_time - last_time.
 pw_chrono_SystemClock_Duration pw_chrono_SystemClock_TimeElapsed(
     pw_chrono_SystemClock_TimePoint last_time,
     pw_chrono_SystemClock_TimePoint current_time);

 // For lossless time unit conversion, the seconds per tick ratio that is
 // numerator/denominator should be used:
 //   PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_NUMERATOR
 //   PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_DENOMINATOR

 // Warning, this may be lossy due to the use of std::chrono::floor,
 // rounding towards zero.
 pw_chrono_SystemClock_Nanoseconds pw_chrono_SystemClock_DurationToNsFloor(
     pw_chrono_SystemClock_Duration duration);

 PW_EXTERN_C_END
	// Copyright 2020 The Pigweed 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.
	#pragma once

	#include <stddef.h>
	#include <stdint.h>

	#include "pw_preprocessor/util.h"

	// The backend implements this header to provide the following SystemClock
	// parameters, for more detail on the parameters see the SystemClock usage of
	// them below:
	// PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_NUMERATOR
	// PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_DENOMINATOR
	// constexpr pw::chrono::Epoch pw::chrono::backend::kSystemClockEpoch;
	// constexpr bool pw::chrono::backend::kSystemClockFreeRunning;
	// constexpr bool pw::chrono::backend::kSystemClockNmiSafe;
	#include "pw_chrono_backend/system_clock_config.h"

	#ifdef __cplusplus

	#include <chrono>
	#include <ratio>

	namespace pw::chrono {
	namespace backend {

	// The ARM AEBI does not permit the opaque 'time_point' to be passed via
	// registers, ergo the underlying fundamental type is forward declared.
	// A SystemCLock tick has the units of one SystemClock::period duration.
	// This must be thread and IRQ safe and provided by the backend.
	int64_t GetSystemClockTickCount();

	} // namespace backend

	// The SystemClock represents an unsteady, monotonic clock.
	//
	// The epoch of this clock is unspecified and may not be related to wall time
	// (for example, it can be time since boot). The time between ticks of this
	// clock may vary due to sleep modes and potential interrupt handling.
	// SystemClock meets the requirements of C++'s TrivialClock and Pigweed's
	// PigweedClock.
	//
	// SystemClock is compatible with C++'s Clock & TrivialClock including:
	// SystemClock::rep
	// SystemClock::period
	// SystemClock::duration
	// SystemClock::time_point
	// SystemClock::is_steady
	// SystemClock::now()
	//
	// Example:
	//
	// SystemClock::time_point before = SystemClock::now();
	// TakesALongTime();
	// SystemClock::duration time_taken = SystemClock::now() - before;
	// bool took_way_too_long = false;
	// if (time_taken > std::chrono::seconds(42)) {
	// took_way_too_long = true;
	// }
	//
	// This code is thread & IRQ safe, it may be NMI safe depending on is_nmi_safe.
	struct SystemClock {
	using rep = int64_t;
	// The period must be provided by the backend.
	using period = std::ratio<PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_NUMERATOR,
	PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_DENOMINATOR>;
	using duration = std::chrono::duration<rep, period>;
	using time_point = std::chrono::time_point<SystemClock>;
	// The epoch must be provided by the backend.
	static constexpr Epoch epoch = backend::kSystemClockEpoch;

	// The time points of this clock cannot decrease, however the time between
	// ticks of this clock may slightly vary due to sleep modes. The duration
	// during sleep may be ignored or backfilled with another clock.
	static constexpr bool is_monotonic = true;
	static constexpr bool is_steady = false;

	// The now() function may not move forward while in a critical section or
	// interrupt. This must be provided by the backend.
	static constexpr bool is_free_running = backend::kSystemClockFreeRunning;

	// The clock must stop while in halting debug mode.
	static constexpr bool is_stopped_in_halting_debug_mode = true;

	// The now() function can be invoked at any time.
	static constexpr bool is_always_enabled = true;

	// The now() function may work in non-masking interrupts, depending on the
	// backend. This must be provided by the backend.
	static constexpr bool is_nmi_safe = backend::kSystemClockNmiSafe;

	// This is thread and IRQ safe. This must be provided by the backend.
	static time_point now() noexcept {
	return time_point(duration(backend::GetSystemClockTickCount()));
	}

	// This is purely a helper, identical to directly using std::chrono::ceil, to
	// convert a duration type which cannot be implicitly converted where the
	// result is rounded up.
	template <class Rep, class Period>
	static constexpr duration for_at_least(std::chrono::duration<Rep, Period> d) {
	return std::chrono::ceil<duration>(d);
	}

	// Computes the nearest time_point after the specified duration has elapsed.
	//
	// This is useful for translating delay or timeout durations into deadlines.
	//
	// The time_point is computed based on now() plus the specified duration
	// where a singular clock tick is added to handle partial ticks. This ensures
	// that a duration of at least 1 tick does not result in [0,1] ticks and
	// instead in [1,2] ticks.
	static time_point TimePointAfterAtLeast(duration after_at_least) {
	return now() + after_at_least + duration(1);
	}
	};

	// An abstract interface representing a SystemClock.
	//
	// This interface allows decoupling code that uses time from the code that
	// creates a point in time. You can use this to your advantage by injecting
	// Clocks into interfaces rather than having implementations call
	// SystemClock::now() directly. However, this comes at a cost of a vtable per
	// implementation and more importantly passing and maintaining references to the
	// VirtualSystemCLock for all of the users.
	//
	// The VirtualSystemClock::RealClock() function returns a reference to the
	// real global SystemClock.
	//
	// Example:
	//
	// void DoFoo(VirtualSystemClock& system_clock) {
	// SystemClock::time_point now = clock.now();
	// // ... Code which consumes now.
	// }
	//
	// // Production code:
	// DoFoo(VirtualSystemCLock::RealClock);
	//
	// // Test code:
	// MockClock test_clock();
	// DoFoo(test_clock);
	//
	// This interface is thread and IRQ safe.
	class VirtualSystemClock {
	public:
	// Returns a reference to the real system clock to aid instantiation.
	static VirtualSystemClock& RealClock();

	virtual ~VirtualSystemClock() = default;
	virtual SystemClock::time_point now() = 0;
	};

	} // namespace pw::chrono

	// The backend can opt to include an inlined implementation of the following:
	// int64_t GetSystemClockTickCount();
	#if __has_include("pw_chrono_backend/system_clock_inline.h")
	#include "pw_chrono_backend/system_clock_inline.h"
	#endif // __has_include("pw_chrono_backend/system_clock_inline.h")

	#endif // __cplusplus

	PW_EXTERN_C_START

	// C API Users should not create pw_chrono_SystemClock_Duration's directly,
	// instead it is strongly recommended to use macros which express the duration
	// in time units, instead of non-portable ticks.
	//
	// The following macros round up just like std::chrono::ceil, this is the
	// recommended rounding to maintain the "at least" contract of timeouts and
	// deadlines (note the *_CEIL macros are the same only more explicit):
	// PW_SYSTEM_CLOCK_MS(milliseconds)
	// PW_SYSTEM_CLOCK_S(seconds)
	// PW_SYSTEM_CLOCK_MIN(minutes)
	// PW_SYSTEM_CLOCK_H(hours)
	// PW_SYSTEM_CLOCK_MS_CEIL(milliseconds)
	// PW_SYSTEM_CLOCK_S_CEIL(seconds)
	// PW_SYSTEM_CLOCK_MIN_CEIL(minutes)
	// PW_SYSTEM_CLOCK_H_CEIL(hours)
	//
	// The following macros round down like std::chrono::{floor,duration_cast},
	// these are discouraged but sometimes necessary:
	// PW_SYSTEM_CLOCK_MS_FLOOR(milliseconds)
	// PW_SYSTEM_CLOCK_S_FLOOR(seconds)
	// PW_SYSTEM_CLOCK_MIN_FLOOR(minutes)
	// PW_SYSTEM_CLOCK_H_FLOOR(hours)
	#include "pw_chrono/internal/system_clock_macros.h"

	typedef struct {
	int64_t ticks;
	} pw_chrono_SystemClock_Duration;

	typedef struct {
	pw_chrono_SystemClock_Duration duration_since_epoch;
	} pw_chrono_SystemClock_TimePoint;
	typedef int64_t pw_chrono_SystemClock_Nanoseconds;

	// Returns the current time, see SystemClock::now() for more detail.
	pw_chrono_SystemClock_TimePoint pw_chrono_SystemClock_Now(void);

	// Returns the change in time between the current_time - last_time.
	pw_chrono_SystemClock_Duration pw_chrono_SystemClock_TimeElapsed(
	pw_chrono_SystemClock_TimePoint last_time,
	pw_chrono_SystemClock_TimePoint current_time);

	// For lossless time unit conversion, the seconds per tick ratio that is
	// numerator/denominator should be used:
	// PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_NUMERATOR
	// PW_CHRONO_SYSTEM_CLOCK_PERIOD_SECONDS_DENOMINATOR

	// Warning, this may be lossy due to the use of std::chrono::floor,
	// rounding towards zero.
	pw_chrono_SystemClock_Nanoseconds pw_chrono_SystemClock_DurationToNsFloor(
	pw_chrono_SystemClock_Duration duration);

	PW_EXTERN_C_END