1113 lines
37 KiB
Plaintext
1113 lines
37 KiB
Plaintext
#
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# For a description of the syntax of this configuration file,
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# see the file kconfig-language.txt in the NuttX tools repository.
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#
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menuconfig DISABLE_OS_API
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bool "Disable NuttX interfaces"
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default y
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---help---
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The following can be used to disable categories of
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APIs supported by the OS. If the compiler supports
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weak functions, then it should not be necessary to
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disable functions unless you want to restrict usage
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of those APIs.
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There are certain dependency relationships in these
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features.
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1) mq_notify logic depends on signals to awaken tasks
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waiting for queues to become full or empty.
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2) pthread_condtimedwait() depends on signals to wake
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up waiting tasks.
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if DISABLE_OS_API
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config DISABLE_POSIX_TIMERS
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bool "Disable POSIX timers"
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default y if DEFAULT_SMALL
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default n if !DEFAULT_SMALL
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config DISABLE_PTHREAD
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bool "Disable pthread support"
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default n
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config DISABLE_SIGNALS
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bool "Disable signal support"
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default n
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config DISABLE_MQUEUE
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bool "Disable POSIX message queue support"
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default n
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config DISABLE_ENVIRON
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bool "Disable environment variable support"
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default y if DEFAULT_SMALL
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default n if !DEFAULT_SMALL
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endif # DISABLE_OS_API
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menu "Clocks and Timers"
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config ARCH_HAVE_TICKLESS
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bool
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config SCHED_TICKLESS
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bool "Support tick-less OS"
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default n
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depends on ARCH_HAVE_TICKLESS
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---help---
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By default, system time is driven by a periodic timer interrupt. An
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alternative configurations is a tick-less configuration in which
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there is no periodic timer interrupt. Instead and interval timer is
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used to schedule the next OS time event. This option selects that
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tick-less OS option. If the tick-less OS is selected, then there are
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additional platform specific interfaces that must be provided as
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defined include/nuttx/arch.h
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if SCHED_TICKLESS
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config SCHED_TICKLESS_ALARM
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bool "Tickless alarm"
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default n
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---help---
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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 allows
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programming events to occur after an interval. With the alarm,
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you can set a time in the future and get an event when that alarm
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goes off. 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 SCHED_TICKLESS_LIMIT_MAX_SLEEP
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bool "Max sleep period (in microseconds)"
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default n
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---help---
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Enables use of the g_oneshot_maxticks variable. This variable is
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initialized by platform-specific logic at runtime to the maximum
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delay that the timer can wait (in configured clock ticks). The
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RTOS tickless logic will then limit all requested delays to this
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value.
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endif
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config USEC_PER_TICK
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int "System timer tick period (microseconds)"
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default 10000 if !SCHED_TICKLESS
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default 100 if SCHED_TICKLESS
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---help---
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In the "normal" configuration where system time is provided by a
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periodic timer interrupt, the default system timer is expected to
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run at 100Hz or USEC_PER_TICK=10000. This setting must be defined
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to inform of NuttX the interval that the the processor hardware is
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providing system timer interrupts to the OS.
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If SCHED_TICKLESS is selected, then there are no system timer
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interrupts. In this case, USEC_PER_TICK does not control any timer
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rates. Rather, it only determines the resolution of time reported
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by clock_systimer() and the resolution of times that can be set for
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certain delays including watchdog timers and delayed work. In this
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case there is a trade-off: It is better to have the USEC_PER_TICK as
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low as possible for higher timing resolution. However, the the time
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is currently held in 'unsigned int' on some systems, this may be
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16-bits but on most contemporary systems it will be 32-bits. In
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either case, smaller values of USEC_PER_TICK will reduce the range
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of values that delays that can be represented. So the trade-off is
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between range and resolution (you could also modify the code to use
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a 64-bit value if you really want both).
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The default, 100 microseconds, will provide for a range of delays
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up to 120 hours.
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This value should never be less than the underlying resolution of
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the timer. Error may ensue.
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if !SCHED_TICKLESS
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config SYSTEMTICK_EXTCLK
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bool "Use external clock"
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default n
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depends on ARCH_HAVE_EXTCLK
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---help---
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Use external clock for system tick. When enabled, the platform-specific
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logic must start its own timer interrupt to make periodic calls to the
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sched_process_timer() or the functions called within. The purpose is
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to move the scheduling off the processor clock to allow entering low
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power states that would disable that clock.
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endif # !SCHED_TICKLESS
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config SYSTEM_TIME64
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bool "64-bit system clock"
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default n
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---help---
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The system timer is incremented at the rate determined by
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USEC_PER_TICK, typically at 100Hz. The count at any given time is
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then the "uptime" in units of system timer ticks. By default, the
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system time is 32-bits wide. Those defaults provide a range of about
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497 days which is probably a sufficient range for "uptime".
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However, if the system timer rate is significantly higher than 100Hz
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and/or if a very long "uptime" is required, then this option can be
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selected to support a 64-bit wide timer.
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config CLOCK_MONOTONIC
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bool "Support CLOCK_MONOTONIC"
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default n
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---help---
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CLOCK_MONOTONIC is an optional standard POSIX clock. Unlike
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CLOCK_REALTIME which can move forward and backward when the
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time-of-day changes, CLOCK_MONOTONIC is the elapsed time since some
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arbitrary point in the post (the system start-up time for NuttX)
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and, hence, is always monotonically increasing. CLOCK_MONOTONIC
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is, hence, the more appropriate clock for determining time
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differences.
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The value of the CLOCK_MONOTONIC clock cannot be set via clock_settime().
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config JULIAN_TIME
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bool "Enables Julian time conversions"
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default n
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---help---
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Enables Julian time conversions
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if !RTC
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config START_YEAR
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int "Start year"
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default 2014
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config START_MONTH
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int "Start month"
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default 1
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config START_DAY
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int "Start day"
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default 1
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endif # !RTC
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config MAX_WDOGPARMS
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int "Maximum number of watchdog parameters"
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default 4
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---help---
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Maximum number of parameters that can be passed to a watchdog handler
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config PREALLOC_WDOGS
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int "Number of pre-allocated watchdog timers"
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default 32
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---help---
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The number of pre-allocated watchdog structures. The system manages
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a pool of preallocated watchdog structures to minimize dynamic
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allocations. Dynamic allocations will still be made if this pool is
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exhausted. You will, however, get better performance and memory
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usage if this value is tuned to minimize such allocations.
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config WDOG_INTRESERVE
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int "Watchdog structures reserved for interrupt handlers"
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default 4
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---help---
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Watchdog structures may be allocated from normal task and also from
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interrupt handlers. Interrupt handlers, however, can only use pre-
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allocated watchdog timer. So, in order to keep normal task
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allocations from exhausting all watchdog structures, a small number
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of pre-allocated watchdog timers must be reserved for exclusive use
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by interrupt handler. This setting determines that number of
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reserved watchdogs.
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config PREALLOC_TIMERS
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int "Number of pre-allocated POSIX timers"
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default 8
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---help---
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The number of pre-allocated POSIX timer structures. The system manages a
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pool of preallocated timer structures to minimize dynamic allocations. Set to
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zero for all dynamic allocations.
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endmenu # Clocks and Timers
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menu "Tasks and Scheduling"
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choice
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prompt "Initialization Task"
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default INIT_ENTRYPOINT if !BUILD_KERNEL
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default INIT_FILEPATH if BUILD_KERNEL && !BINFMT_DISABLE
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default INIT_NONE if BUILD_KERNEL && BINFMT_DISABLE
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config INIT_NONE
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bool "None"
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config INIT_ENTRYPOINT
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bool "Via application entry point"
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depends on !BUILD_KERNEL
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config INIT_FILEPATH
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bool "Via executable file"
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depends on !BINFMT_DISABLE
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endchoice # Initialization task
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if INIT_ENTRYPOINT
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config USER_ENTRYPOINT
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string "Application entry point"
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default "main"
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---help---
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The name of the entry point for user applications. For the example
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applications this is of the form 'app_main' where 'app' is the application
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name. If not defined, USER_ENTRYPOINT defaults to "main".
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endif # INIT_ENTRYPOINT
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if INIT_FILEPATH
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config USER_INITPATH
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string "Application initialization path"
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default "/bin/init"
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---help---
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The name of the entry point for user applications. For the example
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applications this is of the form 'app_main' where 'app' is the application
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name. If not defined, USER_ENTRYPOINT defaults to "main".
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config INIT_SYMTAB
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string "Symbol table"
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default "NULL"
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depends on !BUILD_PROTECTED && !BUILD_KERNEL
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---help---
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The name of othe global array that holds the exported symbol table.
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The special string "NULL" may be provided if there is no symbol
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table. Quotation marks will be stripped when config.h is generated.
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NOTE: This setting cannot be used in protected or kernel builds.
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Any kernel mode symbols tables would not be usable for resolving
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symbols in user mode executables.
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config INIT_NEXPORTS
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string "Symbol table size"
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default "0"
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depends on !BUILD_PROTECTED && !BUILD_KERNEL
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---help---
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The size of the symbol table. NOTE that is is logically a numeric
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value but is represent by a string. That allows you to put
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sizeof(something) or a macro or a global variable name for the
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symbol table size. Quotation marks will be stripped when config.h
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is generated.
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NOTE: This setting cannot be used in protected or kernel builds.
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Any kernel mode symbols tables would not be usable for resolving
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symbols in user mode executables.
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endif # INIT_FILEPATH
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config RR_INTERVAL
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int "Round robin timeslice (MSEC)"
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default 0
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---help---
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The round robin timeslice will be set this number of milliseconds;
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Round roben scheduling (SCHED_RR) is enabled by setting this
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interval to a positive, non-zero value.
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config SCHED_SPORADIC
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bool "Support sporadic scheduling"
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default n
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---help---
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Build in additional logic to support sporadic scheduling
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(SCHED_SPORADIC).
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if SCHED_SPORADIC
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config SCHED_SPORADIC_MAXREPL
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int "Maximum number of replenishments"
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default 3
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range 1 255
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---help---
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Controls the size of allocated replenishment structures and, hence,
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also limits the maximum number of replenishments.
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config SPORADIC_INSTRUMENTATION
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bool "Sporadic scheduler monitor hooks"
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default n
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---help---
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Enables instrumentation in the sporadic scheduler to monitor
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scheduler behavior. If enabled, then the board-specific logic must
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provide the following functions:
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void arch_sporadic_start(FAR struct tcb_s *tcb);
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void arch_sporadic_lowpriority(FAR struct tcb_s *tcb);
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void arch_sporadic_suspend(FAR struct tcb_s *tcb);
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void arch_sporadic_resume(FAR struct tcb_s *tcb);
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endif # SCHED_SPORADIC
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config TASK_NAME_SIZE
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int "Maximum task name size"
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default 31
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---help---
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Spcifies that maximum size of a task name to save in the TCB.
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Useful if scheduler instrumentation is selected. Set to zero to
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disable. Excludes the NUL terminator; the actual allocated size
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willl be TASK_NAME_SIZE + 1. The default of 31 then results in
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a align-able 32-byte allocation.::
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config MAX_TASKS
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int "Max number of tasks"
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default 32
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---help---
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The maximum number of simultaneously active tasks. This value must be
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a power of two.
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config SCHED_HAVE_PARENT
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bool "Support parent/child task relationships"
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default n
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---help---
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Remember the ID of the parent task when a new child task is
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created. This support enables some additional features (such as
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SIGCHLD) and modifies the behavior of other interfaces. For
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example, it makes waitpid() more standards complete by restricting
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the waited-for tasks to the children of the caller. Default:
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disabled.
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config SCHED_CHILD_STATUS
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bool "Retain child exit status"
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default n
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depends on SCHED_HAVE_PARENT
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---help---
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If this option is selected, then the exit status of the child task
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will be retained after the child task exits. This option should be
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selected if you require knowledge of a child process' exit status.
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Without this setting, wait(), waitpid() or waitid() may fail. For
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example, if you do:
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1) Start child task
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2) Wait for exit status (using wait(), waitpid(), or waitid()).
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This can fail because the child task may run to completion before
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the wait begins. There is a non-standard work-around in this case:
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The above sequence will work if you disable pre-emption using
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sched_lock() prior to starting the child task, then re-enable pre-
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emption with sched_unlock() after the wait completes. This works
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because the child task is not permitted to run until the wait is in
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place.
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The standard solution would be to enable SCHED_CHILD_STATUS. In
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this case the exit status of the child task is retained after the
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child exits and the wait will successful obtain the child task's
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exit status whether it is called before the child task exits or not.
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Warning: If you enable this feature, then your application must
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either (1) take responsibility for reaping the child status with wait(),
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waitpid(), or waitid(), or (2) suppress retention of child status.
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If you do not reap the child status, then you have a memory leak and
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your system will eventually fail.
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Retention of child status can be suppressed on the parent using logic like:
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struct sigaction sa;
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sa.sa_handler = SIG_IGN;
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sa.sa_flags = SA_NOCLDWAIT;
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int ret = sigaction(SIGCHLD, &sa, NULL);
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if SCHED_CHILD_STATUS
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config PREALLOC_CHILDSTATUS
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int "Number of pre-allocated child status"
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default 0
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---help---
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To prevent runaway child status allocations and to improve
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allocation performance, child task exit status structures are pre-
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allocated when the system boots. This setting determines the number
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of child status structures that will be pre-allocated. If this
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setting is not defined or if it is defined to be zero then a value
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of 2*MAX_TASKS is used.
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Note that there cannot be more than MAX_TASKS tasks in total.
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However, the number of child status structures may need to be
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significantly larger because this number includes the maximum number
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of tasks that are running PLUS the number of tasks that have exit'ed
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without having their exit status reaped (via wait(), waitid(), or
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waitpid()).
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Obviously, if tasks spawn children indefinitely and never have the
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exit status reaped, then you may have a memory leak! If you enable
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the SCHED_CHILD_STATUS feature, then your application must take
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responsibility for either (1) reaping the child status with wait(),
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waitpid(), or waitid() or it must (2) suppress retention of child
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status. Otherwise, your system will eventually fail.
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Retention of child status can be suppressed on the parent using logic like:
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struct sigaction sa;
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sa.sa_handler = SIG_IGN;
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sa.sa_flags = SA_NOCLDWAIT;
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int ret = sigaction(SIGCHLD, &sa, NULL);
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config DEBUG_CHILDSTATUS
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bool "Enable Child Status Debug Output"
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default n
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depends on SCHED_CHILD_STATUS && DEBUG
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---help---
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Very detailed... I am sure that you do not want this.
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endif # SCHED_CHILD_STATUS
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config SCHED_WAITPID
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bool "Enable waitpid() API"
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default n
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---help---
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Enables the waitpid() interface in a default, non-standard mode
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(non-standard in the sense that the waited for PID need not be child
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of the caller). If SCHED_HAVE_PARENT is also defined, then this
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setting will modify the behavior or waitpid() (making more spec
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compliant) and will enable the waitid() and wait() interfaces as
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well.
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endmenu # Tasks and Scheduling
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menu "Pthread Options"
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depends on !DISABLE_PTHREAD
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config MUTEX_TYPES:
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bool "Enable mutex types"
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default n
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---help---
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Set to enable support for recursive and errorcheck mutexes. Enables
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pthread_mutexattr_settype().
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config NPTHREAD_KEYS
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int "Maximum number of pthread keys"
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default 4
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---help---
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The number of items of thread-
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specific data that can be retained
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endmenu # Pthread Options
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menu "Performance Monitoring"
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config SCHED_CPULOAD
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bool "Enable CPU load monitoring"
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default n
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select SCHED_CPULOAD_EXTCLK if SCHED_TICKLESS
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---help---
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If this option is selected, the timer interrupt handler will monitor
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if the system is IDLE or busy at the time of that the timer interrupt
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occurs. This is a very coarse measurement, but over a period of time,
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it can very accurately determined the percentage of the time that the
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CPU is IDLE.
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The statistics collected in this could be used, for example in the
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PROCFS file system to provide CPU load measurements when read.
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Note that in tickless mode of operation (SCHED_TICKLESS) there is
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no system timer interrupt and CPU load measurements will not be
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possible unless you provide an alternative clock to driver the
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sampling and select SCHED_CPULOAD_EXTCLK.
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if SCHED_CPULOAD
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config SCHED_CPULOAD_EXTCLK
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bool "Use external clock"
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default n
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---help---
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The CPU load measurements are determined by sampling the active
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tasks periodically at the occurrence to a timer expiration. By
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default, the system clock is used to do that sampling.
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There is a serious issue for the accuracy of measurements if the
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system clock is used, however. NuttX threads are often started at
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the time of the system timer expiration. Others may be stopped at
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the time of the system timer expiration (if round-robin time-slicing
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is enabled). Such thread behavior occurs synchronously with the
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system timer and, hence, is not randomly sampled. As a consequence,
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the CPU load attributed to these threads that run synchronously with
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they system timer may be grossly in error.
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The solution is to use some other clock that runs at a different
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rate and has timer expirations that are asynchronous with the
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system timer. Then truly accurate load measurements can be
|
|
achieved. This option enables use of such an "external" clock. The
|
|
implementation of the clock must be provided by platform-specific
|
|
logic; that platform-specific logic must call the system function
|
|
sched_process_cpuload() at each timer expiration with interrupts
|
|
disabled.
|
|
|
|
config SCHED_CPULOAD_TICKSPERSEC
|
|
int "External clock rate"
|
|
default 100
|
|
depends on SCHED_CPULOAD_EXTCLK
|
|
---help---
|
|
If an external clock is used to drive the sampling for the CPU load
|
|
calculations, then this value must be provided. This value provides
|
|
the rate of the external clock in units of ticks per second. The
|
|
default value of 100 corresponds to 100Hz clock. NOTE: that 100Hz
|
|
is the default frequency of the system time and, hence, the worst
|
|
possible choice in most cases.
|
|
|
|
config SCHED_CPULOAD_TIMECONSTANT
|
|
int "CPU load time constant"
|
|
default 2
|
|
---help---
|
|
The accumulated CPU count is divided by two when the accumulated
|
|
tick count exceeds this time constant. This time constant is in
|
|
units of seconds.
|
|
|
|
endif # SCHED_CPULOAD
|
|
|
|
config SCHED_INSTRUMENTATION
|
|
bool "System performance monitor hooks"
|
|
default n
|
|
---help---
|
|
Enables instrumentation in scheduler to monitor system performance.
|
|
If enabled, then the board-specific logic must provide the following
|
|
functions (see include/sched.h):
|
|
|
|
void sched_note_start(FAR struct tcb_s *tcb);
|
|
void sched_note_stop(FAR struct tcb_s *tcb);
|
|
void sched_note_switch(FAR struct tcb_s *pFromTcb, FAR struct tcb_s *pToTcb);
|
|
|
|
endmenu # Performance Monitoring
|
|
|
|
menu "Files and I/O"
|
|
|
|
config DEV_CONSOLE
|
|
bool "Enable /dev/console"
|
|
default y
|
|
---help---
|
|
Set if architecture-specific logic provides /dev/console at boot-up
|
|
time. Enables stdout, stderr, stdin in the start-up application.
|
|
|
|
You need this setting if your console device is ready at boot time.
|
|
For example, if you are using a serial console, then /dev/console
|
|
(aka, /dev/ttyS0) will be available when the application first starts.
|
|
|
|
You must not select DEV_CONSOLE if you console device comes up later
|
|
and is not ready until after the application starts. At this time,
|
|
the only console device that behaves this way is a USB serial console.
|
|
When the application first starts, the USB is (probably) not yet
|
|
connected and /dev/console will not be created until later when the
|
|
host connects to the USB console.
|
|
|
|
config FDCLONE_DISABLE
|
|
bool "Disable cloning of file descriptors"
|
|
default n
|
|
---help---
|
|
Disable cloning of all file descriptors by task_create() when a new
|
|
ask is started. If set, all files/drivers will appear to be closed
|
|
in the new task.
|
|
|
|
config FDCLONE_STDIO
|
|
bool "Disable clone file descriptors without stdio"
|
|
default n
|
|
---help---
|
|
Disable cloning of all but the first three file descriptors (stdin,
|
|
stdout, stderr) by task_create() when a new task is started. If set,
|
|
all files/drivers will appear to be closed in the new task except
|
|
for stdin, stdout, and stderr.
|
|
|
|
config SDCLONE_DISABLE
|
|
bool "Disable cloning of socket descriptors"
|
|
default n
|
|
---help---
|
|
Disable cloning of all socket
|
|
descriptors by task_create() when a new task is started. If
|
|
set, all sockets will appear to be closed in the new task.
|
|
|
|
config NFILE_DESCRIPTORS
|
|
int "Maximum number of file descriptors per task"
|
|
default 16
|
|
---help---
|
|
The maximum number of file descriptors per task (one for each open)
|
|
|
|
config NFILE_STREAMS
|
|
int "Maximum number of FILE streams"
|
|
default 16
|
|
---help---
|
|
The maximum number of streams that can be fopen'ed
|
|
|
|
config NAME_MAX
|
|
int "Maximum size of a file name"
|
|
default 32
|
|
---help---
|
|
The maximum size of a file name.
|
|
|
|
endmenu # Files and I/O
|
|
|
|
menuconfig PRIORITY_INHERITANCE
|
|
bool "Enable priority inheritance "
|
|
default n
|
|
---help---
|
|
Set to enable support for priority inheritance on mutexes and semaphores.
|
|
|
|
if PRIORITY_INHERITANCE
|
|
|
|
config SEM_PREALLOCHOLDERS
|
|
int "Number of pre-allocated holders"
|
|
default 16
|
|
---help---
|
|
This setting is only used if priority inheritance is enabled.
|
|
It defines the maximum number of different threads (minus one) that
|
|
can take counts on a semaphore with priority inheritance support.
|
|
This may be set to zero if priority inheritance is disabled OR if you
|
|
are only using semaphores as mutexes (only one holder) OR if no more
|
|
than two threads participate using a counting semaphore.
|
|
|
|
config SEM_NNESTPRIO
|
|
int "Maximum number of higher priority threads"
|
|
default 16
|
|
---help---
|
|
If priority inheritance is enabled, then this setting is the
|
|
maximum number of higher priority threads (minus 1) than can be
|
|
waiting for another thread to release a count on a semaphore.
|
|
This value may be set to zero if no more than one thread is
|
|
expected to wait for a semaphore.
|
|
|
|
endif # PRIORITY_INHERITANCE
|
|
|
|
menu "RTOS hooks"
|
|
|
|
config BOARD_INITIALIZE
|
|
bool "Custom board/driver initialization"
|
|
default n
|
|
---help---
|
|
By default, there are three points in time where you can insert
|
|
custom initialization logic:
|
|
|
|
1) <arch>_boardinitialize(): This function is used only for
|
|
initialization of very low-level things like configuration of
|
|
GPIO pins, power setting. The OS has not been initialized
|
|
at this point, so you cannot allocate memory or initialize
|
|
device drivers at this phase.
|
|
|
|
2) The next level of initialization is performed by a call to
|
|
up_initialize() (in arch/<arch>/src/common/up_initialize.c).
|
|
The OS has been initialized at this point and it is okay to
|
|
initialize drivers in this phase.
|
|
|
|
3) And, finally, when the user application code starts.
|
|
|
|
If BOARD_INITIALIZE is selected, then an additional initialization
|
|
call will be performed in the boot-up sequence to a function
|
|
called board_initialize(). board_initialize() will be
|
|
call between phases 2) and 3) above, immediately after
|
|
up_initialize() is called. This additional initialization
|
|
phase may be used, for example, to initialize board-specific
|
|
device drivers.
|
|
|
|
if BOARD_INITIALIZE
|
|
|
|
config BOARD_INITTHREAD
|
|
bool "Board initialization thread"
|
|
default n
|
|
---help---
|
|
Some initialization operations cannot be performed on the start-up,
|
|
initialization thread. That is because the initialization thread
|
|
cannot wait for event. If waiting is required as part of the board
|
|
initialization then this option must be selected. Waiting may be
|
|
required, for example, to mount a file system or or initialize a
|
|
device such as an SD card.
|
|
|
|
if BOARD_INITTHREAD
|
|
|
|
config BOARD_INITTHREAD_STACKSIZE
|
|
int "Board initialization thread stack size"
|
|
default 2048
|
|
---help---
|
|
The size of the stack to allocate when starting the board
|
|
initialization thread.
|
|
|
|
config BOARD_INITTHREAD_PRIORITY
|
|
int "Board initialization thread priority"
|
|
default 240
|
|
---help---
|
|
The priority of the board initialization thread. This priority is
|
|
not a critical setting. No other application threads will be
|
|
started until the board initialization is completed. Hence, there
|
|
is very little competition for the CPU.
|
|
|
|
endif # BOARD_INITTHREAD
|
|
endif # BOARD_INITIALIZE
|
|
|
|
config SCHED_STARTHOOK
|
|
bool "Enable startup hook"
|
|
default n
|
|
---help---
|
|
Enable a non-standard, internal OS API call task_starthook().
|
|
task_starthook() registers a function that will be called on task
|
|
startup before that actual task entry point is called. The
|
|
starthook is useful, for example, for setting up automatic
|
|
configuration of C++ constructors.
|
|
|
|
config SCHED_ATEXIT
|
|
bool "Enable atexit() API"
|
|
default n
|
|
---help---
|
|
Enables the atexit() API
|
|
|
|
config SCHED_ATEXIT_MAX
|
|
int "Max number of atexit() functions"
|
|
default 1
|
|
depends on SCHED_ATEXIT && !SCHED_ONEXIT
|
|
---help---
|
|
By default if SCHED_ATEXIT is selected, only a single atexit() function
|
|
is supported. That number can be increased by defined this setting to
|
|
the number that you require.
|
|
|
|
If both SCHED_ONEXIT and SCHED_ATEXIT are selected, then atexit() is built
|
|
on top of the on_exit() implementation. In that case, SCHED_ONEXIT_MAX
|
|
determines the size of the combined number of atexit(0) and on_exit calls
|
|
and SCHED_ATEXIT_MAX is not used.
|
|
|
|
config SCHED_ONEXIT
|
|
bool "Enable on_exit() API"
|
|
default n
|
|
---help---
|
|
Enables the on_exit() API
|
|
|
|
config SCHED_ONEXIT_MAX
|
|
int "Max number of on_exit() functions"
|
|
default 1
|
|
depends on SCHED_ONEXIT
|
|
---help---
|
|
By default if SCHED_ONEXIT is selected, only a single on_exit() function
|
|
is supported. That number can be increased by defined this setting to the
|
|
number that you require.
|
|
|
|
If both SCHED_ONEXIT and SCHED_ATEXIT are selected, then atexit() is built
|
|
on top of the on_exit() implementation. In that case, SCHED_ONEXIT_MAX
|
|
determines the size of the combined number of atexit(0) and on_exit calls.
|
|
|
|
endmenu # RTOS hooks
|
|
|
|
config SIG_EVTHREAD
|
|
bool "Support SIGEV_THHREAD"
|
|
default n
|
|
depends on BUILD_FLAT && SCHED_WORKQUEUE
|
|
---help---
|
|
Built in support for the SIGEV_THREAD signal deliver method.
|
|
|
|
NOTE: The current implementation uses a work queue to notify the
|
|
client. This, however, would only work in the FLAT build. A
|
|
different mechanism would need to be development to support this
|
|
feature on the PROTECTED or KERNEL build.
|
|
|
|
menu "Signal Numbers"
|
|
depends on !DISABLE_SIGNALS
|
|
|
|
config SIG_SIGUSR1
|
|
int "SIGUSR1"
|
|
default 1
|
|
---help---
|
|
Value of standard user signal 1 (SIGUSR1). Default: 1
|
|
|
|
config SIG_SIGUSR2
|
|
int "SIGUSR2"
|
|
default 2
|
|
---help---
|
|
Value of standard user signal 2 (SIGUSR2). Default: 2
|
|
|
|
config SIG_SIGALARM
|
|
int "SIGALRM"
|
|
default 3
|
|
---help---
|
|
Default the signal number used with POSIX timers (SIGALRM).
|
|
Default: 3
|
|
|
|
config SIG_SIGCHLD
|
|
int "SIGCHLD"
|
|
default 4
|
|
depends on SCHED_HAVE_PARENT
|
|
---help---
|
|
The SIGCHLD signal is sent to the parent of a child process when it
|
|
exits, is interrupted (stopped), or resumes after being interrupted.
|
|
Default: 4
|
|
|
|
config SIG_POLL
|
|
int "SIGPOLL"
|
|
default 5
|
|
depends on FS_AIO
|
|
---help---
|
|
The SIGPOLL signal is sent to a process when an asynchronous I/O
|
|
event occurs (meaning it has been polled). Default: 5
|
|
|
|
config SIG_SIGCONDTIMEDOUT
|
|
int "SIGCONDTIMEDOUT"
|
|
default 16
|
|
depends on !DISABLE_PTHREAD
|
|
---help---
|
|
This non-standard signal number is used the implementation of
|
|
pthread_cond_timedwait(). Default 16.
|
|
|
|
config SIG_SIGWORK
|
|
int "SIGWORK"
|
|
default 17
|
|
depends on SCHED_WORKQUEUE || LIB_USRWORK
|
|
---help---
|
|
SIGWORK is a non-standard signal used to wake up the internal NuttX
|
|
worker thread. This setting specifies the signal number that will be
|
|
used for SIGWORK. Default: 17
|
|
|
|
endmenu # Signal Numbers
|
|
|
|
menu "POSIX Message Queue Options"
|
|
depends on !DISABLE_MQUEUE
|
|
|
|
config PREALLOC_MQ_MSGS
|
|
int "Number of pre-allocated messages"
|
|
default 32
|
|
---help---
|
|
The number of pre-allocated message structures. The system manages
|
|
a pool of preallocated message structures to minimize dynamic allocations
|
|
|
|
config MQ_MAXMSGSIZE
|
|
int "Maximum message size"
|
|
default 32
|
|
---help---
|
|
Message structures are allocated with a fixed payload size given by this
|
|
setting (does not include other message structure overhead.
|
|
|
|
endmenu # POSIX Message Queue Options
|
|
|
|
menuconfig MODULE
|
|
bool "Enable loadable OS modules"
|
|
default n
|
|
---help---
|
|
Enable support for loadable OS modules. Default: n
|
|
|
|
if MODULE
|
|
|
|
config MODULE_ALIGN_LOG2
|
|
int "Log2 Section Alignment"
|
|
default 2
|
|
---help---
|
|
Align all sections to this Log2 value: 0->1, 1->2, 2->4, etc.
|
|
|
|
config MODULE_BUFFERSIZE
|
|
int "Module I/O Buffer Size"
|
|
default 128
|
|
---help---
|
|
This is an I/O buffer that is used to access the module file.
|
|
Variable length items will need to be read (such as symbol names).
|
|
This is really just this initial size of the buffer; it will be
|
|
reallocated as necessary to hold large symbol names). Default: 128
|
|
|
|
config MODULE_BUFFERINCR
|
|
int "Module I/O Buffer Realloc Increment"
|
|
default 32
|
|
---help---
|
|
This is an I/O buffer that is used to access the module file.
|
|
Variable length items will need to be read (such as symbol names).
|
|
This value specifies the size increment to use each time the
|
|
buffer is reallocated. Default: 32
|
|
|
|
config MODULE_DUMPBUFFER
|
|
bool "Dump module buffers"
|
|
default n
|
|
depends on DEBUG && DEBUG_VERBOSE
|
|
---help---
|
|
Dump various module buffers for debug purposes
|
|
|
|
endif
|
|
|
|
menu "Work queue support"
|
|
|
|
config SCHED_WORKQUEUE
|
|
# bool "Enable worker thread"
|
|
bool
|
|
default n
|
|
depends on !DISABLE_SIGNALS
|
|
---help---
|
|
Create dedicated "worker" threads to handle delayed or asynchronous
|
|
processing.
|
|
|
|
config SCHED_HPWORK
|
|
bool "High priority (kernel) worker thread"
|
|
default n
|
|
depends on !DISABLE_SIGNALS
|
|
select SCHED_WORKQUEUE
|
|
---help---
|
|
Create a dedicated high-priority "worker" thread to handle delayed
|
|
processing from interrupt handlers. This feature is required for
|
|
some drivers but, if there are no complaints, can be safely
|
|
disabled. The high priority worker thread also performs garbage
|
|
collection -- completing any delayed memory deallocations from
|
|
interrupt handlers. If the high-priority worker thread is disabled,
|
|
then that clean up will be performed either by (1) the low-priority
|
|
worker thread, if enabled, and if not (2) the IDLE thread instead
|
|
(which runs at the lowest of priority and may not be appropriate if
|
|
memory reclamation is of high priority)
|
|
|
|
For other, less-critical asynchronous or delayed process, the
|
|
low-priority worker thread is recommended.
|
|
|
|
if SCHED_HPWORK
|
|
|
|
config SCHED_HPWORKPRIORITY
|
|
int "High priority worker thread priority"
|
|
default 224
|
|
---help---
|
|
The execution priority of the higher priority worker thread.
|
|
|
|
The higher priority worker thread is intended to serve as the
|
|
"bottom" half for device drivers. As a consequence it must run at
|
|
a very high, fixed priority. Typically, it should be the highest
|
|
priority thread in your system. Default: 224
|
|
|
|
For lower priority, application oriented worker thread support,
|
|
please consider enabling the lower priority work queue. The lower
|
|
priority work queue runs at a lower priority, of course, but has
|
|
the added advantage that it supports "priority inheritance" (if
|
|
PRIORITY_INHERITANCE is also selected): The priority of the lower
|
|
priority worker thread can then be adjusted to match the highest
|
|
priority client.
|
|
|
|
config SCHED_HPWORKPERIOD
|
|
int "High priority worker thread period"
|
|
default 100000 if SCHED_LPWORK
|
|
default 50000 if !SCHED_LPWORK
|
|
---help---
|
|
How often the worker thread checks for work in units of microseconds.
|
|
Default: If the high priority worker thread is performing garbage
|
|
collection, then the default is 50*1000 (50 MS). Otherwise, if the
|
|
lower priority worker thread is performing garbage collection, the
|
|
default is 100*1000.
|
|
|
|
config SCHED_HPWORKSTACKSIZE
|
|
int "High priority worker thread stack size"
|
|
default 2048
|
|
---help---
|
|
The stack size allocated for the worker thread. Default: 2K.
|
|
|
|
endif # SCHED_HPWORK
|
|
|
|
config SCHED_LPWORK
|
|
bool "Low priority (kernel) worker thread"
|
|
default n
|
|
depends on !DISABLE_SIGNALS
|
|
select SCHED_WORKQUEUE
|
|
---help---
|
|
If SCHED_LPWORK is defined then a lower-priority work queue will
|
|
be created. This lower priority work queue is better suited for
|
|
more extended, application oriented processing (such as file system
|
|
clean-up operations or asynchronous I/O)
|
|
|
|
if SCHED_LPWORK
|
|
|
|
config SCHED_LPNTHREADS
|
|
int "Number of low-priority worker threads"
|
|
default 1 if !FS_AIO
|
|
default 4 if FS_AIO
|
|
---help---
|
|
This options selects multiple, low-priority threads. This is
|
|
essentially a "thread pool" that provides multi-threaded servicing
|
|
of the low-priority work queue. This breaks the serialization
|
|
of the "queue" (hence, it is no longer a queue at all).
|
|
|
|
This options is required to support, for example, I/O operations
|
|
that stall waiting for input. If there is only a single thread,
|
|
then the entire low-priority queue processing stalls in such cases.
|
|
Such behavior is necessary to support asynchronous I/O, AIO (for example).
|
|
|
|
config SCHED_LPWORKPRIORITY
|
|
int "Low priority worker thread priority"
|
|
default 50
|
|
---help---
|
|
The minimum execution priority of the lower priority worker thread.
|
|
|
|
The lower priority worker thread is intended support application-
|
|
oriented functions. The lower priority work queue runs at a lower
|
|
priority, of course, but has the added advantage that it supports
|
|
"priority inheritance" (if PRIORITY_INHERITANCE is also selected):
|
|
The priority of the lower priority worker thread can then be
|
|
adjusted to match the highest priority client. Default: 50
|
|
|
|
NOTE: This priority inheritance feature is not automatic. The
|
|
lower priority worker thread will always a fixed priority unless
|
|
you implement logic that calls lpwork_boostpriority() to raise the
|
|
priority of the lower priority worker thread (typically called
|
|
before scheduling the work) and then call the matching
|
|
lpwork_restorepriority() when the work is completed (typically
|
|
called within the work handler at the completion of the work).
|
|
Currently, only the NuttX asynchronous I/O logic uses this dynamic
|
|
prioritization feature.
|
|
|
|
The higher priority worker thread, on the other hand, is intended
|
|
to serve as the "bottom" half for device drivers. As a consequence
|
|
it must run at a very high, fixed priority. Typically, it should
|
|
be the highest priority thread in your system.
|
|
|
|
config SCHED_LPWORKPRIOMAX
|
|
int "Low priority worker thread maximum priority"
|
|
default 176
|
|
depends on PRIORITY_INHERITANCE
|
|
---help---
|
|
The maximum execution priority of the lower priority worker thread.
|
|
|
|
The lower priority worker thread is intended support application-
|
|
oriented functions. The lower priority work queue runs at a lower
|
|
priority, of course, but has the added advantage that it supports
|
|
"priority inheritance" (if PRIORITY_INHERITANCE is also selected):
|
|
The priority of the lower priority worker thread can then be
|
|
adjusted to match the highest priority client.
|
|
|
|
The higher priority worker thread, on the other hand, is intended
|
|
to serve as the "bottom" half for device drivers. As a consequence
|
|
it must run at a very high, fixed priority. Typically, it should
|
|
be the highest priority thread in your system.
|
|
|
|
This value provides an upper limit on the priority of the lower
|
|
priority worker thread. This would be necessary, for example, if
|
|
the higher priority worker thread were to defer work to the lower
|
|
priority thread. Clearly, in such a case, you would want to limit
|
|
the maximum priority of the lower priority work thread. Default:
|
|
176
|
|
|
|
config SCHED_LPWORKPERIOD
|
|
int "Low priority worker thread period"
|
|
default 50000
|
|
---help---
|
|
How often the lower priority worker thread checks for work in units
|
|
of microseconds. Default: 50*1000 (50 MS).
|
|
|
|
config SCHED_LPWORKSTACKSIZE
|
|
int "Low priority worker thread stack size"
|
|
default 2048
|
|
---help---
|
|
The stack size allocated for the lower priority worker thread. Default: 2K.
|
|
|
|
endif # SCHED_LPWORK
|
|
endmenu # Work Queue Support
|
|
|
|
menu "Stack and heap information"
|
|
|
|
config IDLETHREAD_STACKSIZE
|
|
int "Idle thread stack size"
|
|
default 1024
|
|
---help---
|
|
The size of the initial stack used by the IDLE thread. The IDLE thread
|
|
is the thread that (1) performs the initial boot of the system up to the
|
|
point where start-up appliation is spawned, and (2) there after is the
|
|
IDLE thread that executes only when there is no other thread ready to run.
|
|
|
|
config USERMAIN_STACKSIZE
|
|
int "Main thread stack size"
|
|
default 2048
|
|
---help---
|
|
The size of the stack to allocate for the user initialization thread
|
|
that is started as soon as the OS completes its initialization.
|
|
|
|
config PTHREAD_STACK_MIN
|
|
int "Minimum pthread stack size"
|
|
default 256
|
|
---help---
|
|
Minimum pthread stack size
|
|
|
|
config PTHREAD_STACK_DEFAULT
|
|
int "Default pthread stack size"
|
|
default 2048
|
|
---help---
|
|
Default pthread stack size
|
|
|
|
endmenu # Stack and heap information
|