594 lines
24 KiB
ReStructuredText
594 lines
24 KiB
ReStructuredText
=====================
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System Time and Clock
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=====================
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Basic System Timer
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==================
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**System Timer** In most implementations, system time is provided
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by a timer interrupt. That timer interrupt runs at rate determined
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by ``CONFIG_USEC_PER_TICK`` (default 10000 microseconds or 100Hz.
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If ``CONFIG_SCHED_TICKLESS`` is selected, the default is 100
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microseconds). The timer generates an interrupt each
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``CONFIG_USEC_PER_TICK`` microseconds and increments a counter
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called ``g_system_timer``. ``g_system_timer`` then provides a
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time-base for calculating *up-time* and elapsed time intervals in
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units of ``CONFIG_USEC_PER_TICK``. The range of ``g_system_timer``
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is, by default, 32-bits. However, if the MCU supports type
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``long long`` and ``CONFIG_SYSTEM_TIME16`` is selected, a 64-bit
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system timer will be supported instead.
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**System Timer Accuracy** On many system, the exact timer interval
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specified by ``CONFIG_USEC_PER_TICK`` cannot be achieved due to
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limitations in frequencies or in dividers. As a result, the time
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interval specified by ``CONFIG_USEC_PER_TICK`` may only be
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approximate and there may be small errors in the apparent
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*up-time* time. These small errors, however, will accumulate over
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time and after a long period of time may have an unacceptably
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large error in the apparent *up-time* of the MCU.
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If the timer tick period generated by the hardware is not exactly
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``CONFIG_USEC_PER_TICK`` *and* if there you require accurate
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up-time for the MCU, then there are measures that you can take:
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- Perhaps you can adjust ``CONFIG_USEC_PER_TICK`` to a different
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value so that an exactly ``CONFIG_USEC_PER_TICK`` can be
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realized.
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- Or you can use a technique known as *Delta-Sigma Modulation*.
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(Suggested by Uros Platise). Consider the example below.
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**Delta-Sigma Modulation Example**. Consider this case: The system
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timer is a count-up timer driven at 32.768KHz. There are dividers
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that can be used, but a divider of one yields the highest
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accuracy. This counter counts up until the count equals a match
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value, then a timer interrupt is generated. The desire frequency
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is 100Hz (``CONFIG_USEC_PER_TICK`` is 10000).
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This exact frequency of 100Hz cannot be obtained in this case. In
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order to obtain that exact frequency a match value of 327.68 would
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have to be provided. The closest integer value is 328 but the
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ideal match value is between 327 and 328. The closest value, 328,
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would yield an actual timer frequency of 99.9Hz! That will may
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cause significant timing errors in certain usages.
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Use of Delta-Sigma Modulation can eliminate this error in the long
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run. Consider this example implementation:
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#. Initially an accumulator is zero an the match value is
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programmed to 328:
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.. code-block:: c
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accumulator = 0;
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match = 328;
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#. On each timer interrupt, accumulator is updated with difference
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that, in this reflects, 100\* the error in interval that just
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passed. So on the first timer interrupt, the accumulator would
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be updated like:
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.. code-block:: c
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if (match == 328)
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{
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accumulator += 32; // 100*(328 - 327.68)
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}
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else
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{
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accumulator -= 68; // (100*(327 - 327.68)
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}
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#. And on that same timer interrupt a new match value would be
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programmed:
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.. code-block:: c
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if (accumulator < 0)
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{
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match = 328;
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}
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else
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{
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match = 327;
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}
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In this way, the timer interval is controlled from
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interrupt-to-interrupt to produce an average frequency of exactly
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100Hz.
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Hardware
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========
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To enable hardware module use the following configuration options:
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``CONFIG_RTC``
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Enables general support for a hardware RTC. Specific
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architectures may require other specific settings.
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``CONFIG_RTC_EXTERNAL``
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Most MCUs include RTC hardware built into the chip. Other RTCs,
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*external* MCUs, may be provided as separate chips typically
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interfacing with the MCU via a serial interface such as SPI or
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I2C. These external RTCs differ from the built-in RTCs in that
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they cannot be initialized until the operating system is fully
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booted and can support the required serial communications.
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``CONFIG_RTC_EXTERNAL`` will configure the operating system so
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that it defers initialization of its time facilities.
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``CONFIG_RTC_DATETIME``
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There are two general types of RTC: (1) A simple battery backed
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counter that keeps the time when power is down, and (2) A full
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date / time RTC the provides the date and time information,
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often in BCD format. If ``CONFIG_RTC_DATETIME`` is selected, it
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specifies this second kind of RTC. In this case, the RTC is
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used to "seed"" the normal NuttX timer and the NuttX system
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timer provides for higher resolution time.
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``CONFIG_RTC_HIRES``
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If ``CONFIG_RTC_DATETIME`` not selected, then the simple,
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battery backed counter is used. There are two different
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implementations of such simple counters based on the time
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resolution of the counter: The typical RTC keeps time to
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resolution of 1 second, usually supporting a 32-bit ``time_t``
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value. In this case, the RTC is used to "seed" the normal NuttX
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timer and the NuttX timer provides for higher resolution time.
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If ``CONFIG_RTC_HIRES`` is enabled in the NuttX configuration,
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then the RTC provides higher resolution time and completely
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replaces the system timer for purpose of date and time.
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``CONFIG_RTC_FREQUENCY``
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If ``CONFIG_RTC_HIRES`` is defined, then the frequency of the
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high resolution RTC must be provided. If ``CONFIG_RTC_HIRES``
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is not defined, ``CONFIG_RTC_FREQUENCY`` is assumed to be one.
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``CONFIG_RTC_ALARM``
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Enable if the RTC hardware supports setting of an alarm. A
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callback function will be executed when the alarm goes off
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which requires the following base functions to read and set time:
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- ``up_rtc_initialize()``. Initialize the built-in, MCU hardware
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RTC per the selected configuration. This function is called
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once very early in the OS initialization sequence. NOTE that
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initialization of external RTC hardware that depends on the
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availability of OS resources (such as SPI or I2C) must be
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deferred until the system has fully booted. Other, RTC-specific
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initialization functions are used in that case.
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- ``up_rtc_time()``. Get the current time in seconds. This is
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similar to the standard ``time()`` function. This interface is
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only required if the low-resolution RTC/counter hardware
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implementation selected. It is only used by the RTOS during
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initialization to set up the system time when ``CONFIG_RTC`` is
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set but neither ``CONFIG_RTC_HIRES`` nor
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``CONFIG_RTC_DATETIME`` are set.
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- ``up_rtc_gettime()``. Get the current time from the high
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resolution RTC clock/counter. This interface is only supported
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by the high-resolution RTC/counter hardware implementation. It
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is used to replace the system timer (``g_system_tick``).
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- ``up_rtc_settime()``. Set the RTC to the provided time. All RTC
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implementations must be able to set their time based on a
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standard timespec.
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System Tick and Time
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====================
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The system tick is represented by ``g_system_timer``.
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Running at rate of system base timer, used for time-slicing, and
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so forth.
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If hardware RTC is present (``CONFIG_RTC``) and and
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high-resolution timing is enabled (``CONFIG_RTC_HIRES``), then
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after successful initialization variables are overridden by calls
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to ``up_rtc_gettime()`` which is running continuously even in
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power-down modes.
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In the case of ``CONFIG_RTC_HIRES`` is set the ``g_system_timer``
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keeps counting at rate of a system timer, which however, is
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disabled in power-down mode. By comparing this time and RTC
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(actual time) one may determine the actual system active time. To
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retrieve that variable use:
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Tickless OS
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===========
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**Default System Timer**. By default, a NuttX configuration uses a
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periodic timer interrupt that drives all system timing. The timer
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is provided by architecture-specific code that calls into NuttX at
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a rate controlled by ``CONFIG_USEC_PER_TICK``. The default value
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of ``CONFIG_USEC_PER_TICK`` is 10000 microseconds which
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corresponds to a timer interrupt rate of 100 Hz.
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On each timer interrupt, NuttX does these things:
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- Increments a counter. This counter is the system time and has a
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resolution of ``CONFIG_USEC_PER_TICK`` microseconds.
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- Checks if it is time to perform time-slice operations on tasks
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that have select round-robin scheduling.
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- Checks for expiration of timed events.
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What is wrong with this default system timer? Nothing really. It
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is reliable and uses only a small fraction of the CPU band width.
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But we can do better. Some limitations of default system timer
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are, in increasing order of importance:
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- **Overhead**: Although the CPU usage of the system timer
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interrupt at 100Hz is really very low, it is still mostly
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wasted processing time. One most timer interrupts, there is
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really nothing that needs be done other than incrementing the
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counter.
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- **Resolution**: Resolution of all system timing is also
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determined by ``CONFIG_USEC_PER_TICK``. So nothing that be time
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with resolution finer than 10 milliseconds be default. To
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increase this resolution, ``CONFIG_USEC_PER_TICK`` an be
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reduced. However, then the system timer interrupts use more of
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the CPU bandwidth processing useless interrupts.
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- **Power Usage**: But the biggest issue is power usage. When the
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system is IDLE, it enters a light, low-power mode (for ARMs,
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this mode is entered with the ``wfi`` or ``wfe`` instructions
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for example). But each interrupt awakens the system from this
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low power mode. Therefore, higher rates of interrupts cause
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greater power consumption.
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**Tickless OS**. The so-called *Tickless OS* provides one solution
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to issue. The basic concept here is that the periodic, timer
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interrupt is eliminated and replaced with a one-shot, interval
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timer. It becomes event driven instead of polled: The default
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system timer is a polled design. On each interrupt, the NuttX
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logic checks if it needs to do anything and, if so, it does it.
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Using an interval timer, one can anticipate when the next
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interesting OS event will occur, program the interval time and
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wait for it to fire. When the interval time fires, then the
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scheduled activity is performed.
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Tickless Platform Support
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-------------------------
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In order to use the Tickless OS, one must provide special support
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from the platform-specific code. Just as with the default system
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timer, the platform-specific code must provide the timer resources
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to support the OS behavior. Currently these timer resources are
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only provided on a few platforms. An example implementation is for
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the simulation is at ``nuttx/arch/sim/src/up_tickless.c``. There
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is another example for the Atmel SAMA5 at
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``nuttx/arch/arm/src/sama5/sam_tickless.c``. These paragraphs will
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explain how to provide the Tickless OS support to any platform.
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Tickless Configuration Options
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------------------------------
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- ``CONFIG_ARCH_HAVE_TICKLESS``: If the platform provides
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support for the *Tickless OS*, then this setting should be
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selected in the ``Kconfig`` file for the board. Here is what
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the selection looks in the ``arch/Kconfig`` file for the
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simulated platform:
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When the simulation platform is selected,
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``ARCH_HAVE_TICKLESS`` is automatically selected, informing the
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configuration system that *Tickless OS* options can be
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selected.
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- ``CONFIG_SCHED_TICKLESS``: If ``CONFIG_ARCH_HAVE_TICKLESS``
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is selected, then it will enable the Tickless OS features in
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NuttX.
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- ``CONFIG_SCHED_TICKLESS_ALARM``: The tickless option can be
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supported either via a simple interval timer (plus elapsed
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time) or via an alarm. The interval timer allows programming
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events to occur after an interval. With the alarm, you can set
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a time in the future and get an event when that alarm goes off.
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This option selects the use of an alarm.
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The advantage of an alarm is that it avoids some small timing
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errors; the advantage of the use of the interval timer is that
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the hardware requirement may be less.
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- ``CONFIG_USEC_PER_TICK``: This option is not unique to
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*Tickless OS* operation, but changes its relevance when the
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*Tickless OS* is selected. In the default configuration where
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system time is provided by a periodic timer interrupt, the
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default system timer is configure the timer for 100Hz or
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``CONFIG_USEC_PER_TICK=10000``. If ``CONFIG_SCHED_TICKLESS`` is
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selected, then there are no system timer interrupt. In this
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case, ``CONFIG_USEC_PER_TICK`` does not control any timer
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rates. Rather, it only determines the resolution of time
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reported by ``clock_systime_ticks()`` and the resolution of
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times that can be set for certain delays including watchdog
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timers and delayed work.
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In this case there is still a trade-off: It is better to have
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the ``CONFIG_USEC_PER_TICK`` as low as possible for higher
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timing resolution. However, the time is currently held in
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``unsigned int``. On some systems, this may be 16-bits in width
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but on most contemporary systems it will be 32-bits. In either
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case, smaller values of ``CONFIG_USEC_PER_TICK`` will reduce
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the range of values that delays that can be represented. So the
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trade-off is between range and resolution (you could also
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modify the code to use a 64-bit value if you really want both).
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The default, 100 microseconds, will provide for a range of
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delays up to 120 hours.
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This value should never be less than the underlying resolution
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of the timer. Errors may ensue.
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Tickless Imported Interfaces
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----------------------------
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The interfaces that must be provided by the platform specified
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code are defined in ``include/nuttx/arch.h``, listed below, and
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summarized in the following paragraphs:
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- ``<arch>_timer_initialize()`` Initializes
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the timer facilities. Called early in the initialization
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sequence (by ``up_initialize()``).
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- ``up_timer_gettime()``: Returns the
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current time from the platform specific time source.
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The tickless option can be supported either via a simple interval
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timer (plus elapsed time) or via an alarm. The interval timer
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allows programming events to occur after an interval. With the
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alarm, you can set a time in\* the future and get an event when
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that alarm goes off.
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If ``CONFIG_SCHED_TICKLESS_ALARM`` is defined, then the platform
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code must provide the following:
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- ``up_alarm_cancel()``: Cancels the alarm.
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- ``up_alarm_start()``: Enables (or
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re-enables) the alarm.
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If ``CONFIG_SCHED_TICKLESS_ALARM`` is *not*\ defined, then the
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platform code must provide the following verify similar functions:
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- ``up_timer_cancel()``: Cancels the
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interval timer.
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- ``up_timer_start()``: Starts (or re-starts)
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the interval timer.
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Note that a platform-specific implementation would probably
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require two hardware timers: (1) A interval timer to satisfy the
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requirements of ``up_timer_start()`` and
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``up_timer_cancel()``, and a (2) a counter to
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handle the requirement of
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``up_timer_gettime()``. Ideally, both timers
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would run at the rate determined by ``CONFIG_USEC_PER_TICK`` (and
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certainly never slower than that rate).
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Since timers are a limited resource, the use of two timers could
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be an issue on some systems. The job could be done with a single
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timer if, for example, the single timer were kept in a
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free-running at all times. Some timer/counters have the capability
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to generate a compare interrupt when the timer matches a
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comparison value but also to continue counting without stopping.
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If your hardware supports such counters, one might used the
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``CONFIG_SCHED_TICKLESS_ALARM`` option and be able to simply set
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the comparison count at the value of the free running timer *PLUS*
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the desired delay. Then you could have both with a single timer:
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An alarm and a free-running counter with the same timer!
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In addition to these imported interfaces, the RTOS will export the
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following interfaces for use by the platform-specific interval
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timer implementation:
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- ``nxsched_alarm_expiration()``: called by the platform-specific logic when the alarm expires.
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- ``nxsched_timer_expiration()``: called by the platform-specific logic when the interval time expires.
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.. c:function:: void archname_timer_initialize(void)
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Initializes all platform-specific timer facilities. This function is
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called early in the initialization sequence by up_initialize().
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On return, the current up-time should be available from up_timer_gettime()
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and the interval timer is ready for use (but not actively timing).
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The naming will depend on the architecture so for STM32 ``archname`` will
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be ``stm32``.
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:return: Zero (OK) on success; a negated errno value on failure.
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**Assumptions**: Called early in the initialization sequence before
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any special concurrency protections are required.
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.. c:function:: int up_timer_gettime(FAR struct timespec *ts)
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Return the elapsed time since power-up (or, more correctly, since
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*<arch>*\ ``_timer_initialize()`` was called). This function is
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functionally equivalent to ``clock_gettime()`` for the clock ID
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``CLOCK_MONOTONIC``. This function provides the basis for
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reporting the current time and also is used to eliminate error
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build-up from small errors in interval time calculations.
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:param ts: Provides the location in which to return the up-time..
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:return: Zero (OK) on success; a negated errno value on failure.
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**Assumptions**: Called from the normal tasking context. The
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implementation must provide whatever mutual exclusion is necessary
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for correct operation. This can include disabling interrupts in
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order to assure atomic register operations.
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.. c:function:: int up_alarm_cancel(FAR struct timespec *ts)
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Cancel the alarm and return the time of cancellation of the alarm.
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These two steps need to be as nearly atomic as possible.
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``nxsched_timer_expiration()`` will not be called unless the alarm
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is restarted with ``up_alarm_start()``. If, as a race condition,
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the alarm has already expired when this function is called, then
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time returned is the current time.
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:param ts: Location to return the expiration time. The current
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time should be returned if the timer is not active. ``ts`` may
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be ``NULL`` in which case the time is not returned
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:return: Zero (OK) on success; a negated errno value on failure.
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**Assumptions**: May be called from interrupt level handling or
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from the normal tasking level. interrupts may need to be disabled
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internally to assure non-reentrancy.
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.. c:function:: int up_alarm_start(FAR const struct timespec *ts)
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Start the alarm. ``nxsched_timer_expiration()`` will be called
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when the alarm occurs (unless ``up_alarm_cancel`` is called to
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stop it).
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:param ts: The time in the future at the alarm is expected to
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occur. When the alarm occurs the timer logic will call
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``nxsched_timer_expiration()``.
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:return: Zero (OK) on success; a negated errno value on failure.
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**Assumptions**: May be called from interrupt level handling or
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from the normal tasking level. Interrupts may need to be
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disabled internally to assure non-reentrancy.
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.. c:function:: int up_timer_cancel(FAR struct timespec *ts)
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Cancel the interval timer and return the time remaining on the
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timer. These two steps need to be as nearly atomic as possible.
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``nxsched_timer_expiration()`` will not be called unless the timer
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is restarted with ``up_timer_start()``. If, as a race condition,
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the timer has already expired when this function is called, then
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that pending interrupt must be cleared so that
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``nxsched_timer_expiration()`` is not called spuriously and the
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remaining time of zero should be returned.
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:param ts: Location to return the remaining time. Zero should be
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returned if the timer is not active.
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:return: Zero (OK) on success; a negated errno value on failure.
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**Assumptions**: May be called from interrupt level handling or
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from the normal tasking level. interrupts may need to be
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disabled internally to assure non-reentrancy.
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.. c:function:: int up_timer_start(FAR const struct timespec *ts)
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Start the interval timer. ``nxsched_timer_expiration()`` will be
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called at the completion of the timeout (unless
|
|
``up_timer_cancel()`` is called to stop the timing).
|
|
|
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:param ts: Provides the time interval until
|
|
``nxsched_timer_expiration()`` is called.
|
|
|
|
:return: Zero (OK) on success; a negated errno value on failure.
|
|
|
|
**Assumptions**: May be called from interrupt level handling
|
|
or from the normal tasking level. Interrupts may need to be
|
|
disabled internally to assure non-reentrancy.
|
|
|
|
Watchdog Timer Interfaces
|
|
=========================
|
|
|
|
NuttX provides a general watchdog timer facility. This facility
|
|
allows the NuttX user to specify a watchdog timer function that
|
|
will run after a specified delay. The watchdog timer function will
|
|
run in the context of the timer interrupt handler. Because of
|
|
this, a limited number of NuttX interfaces are available to he
|
|
watchdog timer function. However, the watchdog timer function may
|
|
use ``mq_send()``, ``sigqueue()``, or ``kill()`` to communicate
|
|
with NuttX tasks.
|
|
|
|
- :c:func:`wd_start`
|
|
- :c:func:`wd_cancel`
|
|
- :c:func:`wd_gettime`
|
|
- Watchdog Timer Callback
|
|
|
|
.. c:function:: int wd_start(FAR struct wdog_s *wdog, int delay, \
|
|
wdentry_t wdentry, wdparm_t arg)
|
|
|
|
This function adds a watchdog to the timer queue.
|
|
The specified watchdog function will be called from the interrupt
|
|
level after the specified number of ticks has elapsed. Watchdog
|
|
timers may be started from the interrupt level.
|
|
|
|
Watchdog times execute in the context of the timer interrupt
|
|
handler.
|
|
|
|
Watchdog timers execute only once.
|
|
|
|
To replace either the timeout delay or the function to be
|
|
executed, call wd_start again with the same wdog; only the most
|
|
recent wd_start() on a given watchdog ID has any effect.
|
|
|
|
:param wdog: Watchdog ID
|
|
:param delay: Delay count in clock ticks
|
|
:param wdentry: Function to call on timeout
|
|
:param arg: The parameter to pass to wdentry.
|
|
|
|
**NOTE**: The parameter must be of type ``wdparm_t``.
|
|
|
|
:return: Zero (``OK``) is returned on success; a negated ``errno`` value
|
|
is return to indicate the nature of any failure.
|
|
|
|
**Assumptions/Limitations:** The watchdog routine runs in the
|
|
context of the timer interrupt handler and is subject to all ISR
|
|
restrictions.
|
|
|
|
**POSIX Compatibility:** This is a NON-POSIX interface. VxWorks
|
|
provides the following comparable interface:
|
|
|
|
.. code-block:: c
|
|
|
|
STATUS wdStart (WDOG_ID wdog, int delay, FUNCPTR wdentry, int parameter);
|
|
|
|
Differences from the VxWorks interface include:
|
|
|
|
- The present implementation supports multiple parameters passed
|
|
to wdentry; VxWorks supports only a single parameter. The
|
|
maximum number of parameters is determined by
|
|
|
|
.. c:function:: int wd_cancel(FAR struct wdog_s *wdog)
|
|
|
|
This function cancels a currently running
|
|
watchdog timer. Watchdog timers may be canceled from the interrupt
|
|
level.
|
|
|
|
:param wdog: ID of the watchdog to cancel.
|
|
|
|
:return: ``OK`` or ``ERROR``
|
|
|
|
|
|
**POSIX Compatibility:** This is a NON-POSIX interface. VxWorks
|
|
provides the following comparable interface:
|
|
|
|
.. code-block:: c
|
|
|
|
STATUS wdCancel (WDOG_ID wdog);
|
|
|
|
.. c:function:: int wd_gettime(FAR struct wdog_s *wdog)
|
|
|
|
Returns the time remaining before
|
|
the specified watchdog expires.
|
|
|
|
:param wdog: Identifies the watchdog that the request is for.
|
|
|
|
:return: The time in system ticks remaining until the
|
|
watchdog time expires. Zero means either that wdog is not valid or
|
|
that the wdog has already expired.
|
|
|
|
.. c:type:: void (*wdentry_t)(wdparm_t arg)
|
|
|
|
**Watchdog Timer Callback**: when a watchdog expires,
|
|
the callback function with this type is
|
|
called.
|
|
|
|
The argument is passed as scalar ``wdparm_t`` values. For
|
|
systems where the ``sizeof(pointer) < sizeof(uint32_t)``, the
|
|
following union defines the alignment of the pointer within the
|
|
``uint32_t``. For example, the SDCC MCS51 general pointer is
|
|
24-bits, but ``uint32_t`` is 32-bits (of course).
|
|
|
|
We always have ``sizeof(pointer) <= sizeof(uintptr_t)`` by
|
|
definition.
|
|
|
|
.. code-block:: c
|
|
|
|
union wdparm_u
|
|
{
|
|
FAR void *pvarg; /* The size one generic point */
|
|
uint32_t dwarg; /* Big enough for a 32-bit value in any case */
|
|
uintptr_t uiarg; /* sizeof(uintptr_t) >= sizeof(pointer) */
|
|
};
|
|
|
|
#if UINTPTR_MAX >= UINT32_MAX
|
|
typedef uintptr_t wdparm_t;
|
|
#else
|
|
typedef uint32_t wdparm_t;
|
|
#endif
|