.. SPDX-License-Identifier: CC-BY-SA-4.0 .. Copyright (C) 1988, 2008 On-Line Applications Research Corporation (OAR) General System Configuration ============================ This section defines the general system configuration options supported by ````. .. index:: CONFIGURE_DIRTY_MEMORY .. _CONFIGURE_DIRTY_MEMORY: CONFIGURE_DIRTY_MEMORY ---------------------- CONSTANT: ``CONFIGURE_DIRTY_MEMORY`` DATA TYPE: Boolean feature macro. RANGE: Defined or undefined. DEFAULT VALUE: By default, the memory used by the RTEMS Workspace and the C Program Heap is uninitialized memory. DESCRIPTION: This macro indicates whether RTEMS should dirty the memory used by the RTEMS Workspace and the C Program Heap as part of its initialization. If defined, the memory areas are dirtied with a ``0xCF`` byte pattern. Otherwise, they are not. NOTES: Dirtying memory can add significantly to system boot time. It may assist in finding code that incorrectly assumes the contents of free memory areas is cleared to zero during system initialization. In case :ref:`CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY` is also defined, then the memory is first dirtied and then zeroed. .. index:: CONFIGURE_EXTRA_TASK_STACKS .. index:: memory for task tasks .. _CONFIGURE_EXTRA_TASK_STACKS: CONFIGURE_EXTRA_TASK_STACKS --------------------------- CONSTANT: ``CONFIGURE_EXTRA_TASK_STACKS`` DATA TYPE: Unsigned integer (``size_t``). RANGE: Undefined or positive. DEFAULT VALUE: The default value is 0. DESCRIPTION: This configuration parameter is set to the number of bytes the applications wishes to add to the task stack requirements calculated by ````. NOTES: This parameter is very important. If the application creates tasks with stacks larger then the minimum, then that memory is NOT accounted for by ````. .. index:: CONFIGURE_INITIAL_EXTENSIONS .. _CONFIGURE_INITIAL_EXTENSIONS: CONFIGURE_INITIAL_EXTENSIONS ---------------------------- CONSTANT: ``CONFIGURE_INITIAL_EXTENSIONS`` DATA TYPE: List of user extension initializers (``rtems_extensions_table``). RANGE: Undefined or a list of one or more user extensions. DEFAULT VALUE: This is not defined by default. DESCRIPTION: If ``CONFIGURE_INITIAL_EXTENSIONS`` is defined by the application, then this application specific set of initial extensions will be placed in the initial extension table. NOTES: None. .. index:: CONFIGURE_INTERRUPT_STACK_SIZE .. index:: interrupt stack size .. _CONFIGURE_INTERRUPT_STACK_SIZE: CONFIGURE_INTERRUPT_STACK_SIZE ------------------------------ CONSTANT: ``CONFIGURE_INTERRUPT_STACK_SIZE`` DATA TYPE: Unsigned integer. RANGE: Positive. DEFAULT VALUE: The default value is ``BSP_INTERRUPT_STACK_SIZE`` in case it is defined, otherwise the default value is ``CPU_STACK_MINIMUM_SIZE``. DESCRIPTION: The ``CONFIGURE_INTERRUPT_STACK_SIZE`` configuration option defines the size of an interrupt stack in bytes. NOTES: The interrupt stack size must be aligned according to ``CPU_INTERRUPT_STACK_ALIGNMENT``. There is one interrupt stack available for each configured processor (:ref:`CONFIGURE_MAXIMUM_PROCESSORS `). The interrupt stack areas are statically allocated in a special linker section (``.rtemsstack.interrupt``). The placement of this linker section is BSP-specific. Some BSPs use the interrupt stack as the initialization stack which is used to perform the sequential system initialization before the multithreading is started. The interrupt stacks are covered by the :ref:`stack checker `. However, using a too small interrupt stack size may still result in undefined behaviour. In releases before RTEMS 5.1 the default value was :ref:`CONFIGURE_MINIMUM_TASK_STACK_SIZE ` instead of ``CPU_STACK_MINIMUM_SIZE``. .. index:: CONFIGURE_MAXIMUM_FILE_DESCRIPTORS .. index:: maximum file descriptors .. _CONFIGURE_MAXIMUM_FILE_DESCRIPTORS: CONFIGURE_MAXIMUM_FILE_DESCRIPTORS ---------------------------------- CONSTANT: ``CONFIGURE_MAXIMUM_FILE_DESCRIPTORS`` DATA TYPE: Unsigned integer (``uint32_t``). RANGE: Zero or positive. DEFAULT VALUE: If ``CONFIGURE_APPLICATION_NEEDS_CONSOLE_DRIVER`` is defined, then the default value is 3, otherwise the default value is 0. Three file descriptors allows RTEMS to support standard input, output, and error I/O streams on ``/dev/console``. DESCRIPTION: This configuration parameter is set to the maximum number of file like objects that can be concurrently open. NOTES: None. .. index:: CONFIGURE_MAXIMUM_PRIORITY .. index:: maximum priority .. index:: number of priority levels .. _CONFIGURE_MAXIMUM_PRIORITY: CONFIGURE_MAXIMUM_PRIORITY -------------------------- CONSTANT: ``CONFIGURE_MAXIMUM_PRIORITY`` DATA TYPE: Unsigned integer (``uint8_t``). RANGE: Valid values for this configuration parameter must be one (1) less than than a power of two (2) between 4 and 256 inclusively. In other words, valid values are 3, 7, 31, 63, 127, and 255. DEFAULT VALUE: The default value is 255, because RTEMS must support 256 priority levels to be compliant with various standards. These priorities range from zero (0) to 255. DESCRIPTION: For the schedulers * :ref:`SchedulerPriority`, which is the default in uniprocessor configurations and can be configured through the :ref:`CONFIGURE_SCHEDULER_PRIORITY` configuration option, * :ref:`SchedulerSMPPriority` which can be configured through the :ref:`CONFIGURE_SCHEDULER_PRIORITY_SMP` configuration option, and * :ref:`SchedulerSMPPriorityAffinity` which can be configured through the :ref:`CONFIGURE_SCHEDULER_PRIORITY_AFFINITY_SMP` configuration option this configuration option specifies the maximum numeric priority of any task for these schedulers and one less that the number of priority levels for these schedulers. For all other schedulers provided by RTEMS, this configuration option has no effect. NOTES: The numerically greatest priority is the logically lowest priority in the system and will thus be used by the IDLE task. Priority zero (0) is reserved for internal use by RTEMS and is not available to applications. Reducing the number of priorities through this configuration option reduces the amount of memory allocated by the schedulers listed above. These schedulers use a chain control structure per priority and this structure consists of three pointers. On a 32-bit architecture, the allocated memory is 12 bytes * (``CONFIGURE_MAXIMUM_PRIORITY`` + 1), e.g. 3072 bytes for 256 priority levels (default), 48 bytes for 4 priority levels (``CONFIGURE_MAXIMUM_PRIORITY == 3``). .. index:: CONFIGURE_MAXIMUM_PROCESSORS .. _CONFIGURE_MAXIMUM_PROCESSORS: CONFIGURE_MAXIMUM_PROCESSORS ---------------------------- CONSTANT: ``CONFIGURE_MAXIMUM_PROCESSORS`` DATA TYPE: Unsigned integer (``uint32_t``). RANGE: Positive. DEFAULT VALUE: The default value is 1. DESCRIPTION: ``CONFIGURE_MAXIMUM_PROCESSORS`` must be set to the maximum number of processors an application intends to use. The number of actually available processors depends on the hardware and may be less. It is recommended to use the smallest value suitable for the application in order to save memory. Each processor needs an idle thread and interrupt stack for example. NOTES: If there are more processors available than configured, the rest will be ignored. This configuration define is ignored in uniprocessor configurations. .. index:: CONFIGURE_MAXIMUM_THREAD_NAME_SIZE .. index:: maximum thread name size .. _CONFIGURE_MAXIMUM_THREAD_NAME_SIZE: CONFIGURE_MAXIMUM_THREAD_NAME_SIZE ---------------------------------- CONSTANT: ``CONFIGURE_MAXIMUM_THREAD_NAME_SIZE`` DATA TYPE: Unsigned integer (``size_t``). RANGE: No restrictions. DEFAULT VALUE: The default value is 16. This value was chosen for Linux compatibility, see `PTHREAD_SETNAME_NP(3) `_. DESCRIPTION: This configuration parameter specifies the maximum thread name size including the terminating `NUL` character. NOTE: The size of the thread control block is increased by the maximum thread name size. This configuration option is available since RTEMS 5.1. .. index:: CONFIGURE_MEMORY_OVERHEAD .. _CONFIGURE_MEMORY_OVERHEAD: CONFIGURE_MEMORY_OVERHEAD ------------------------- CONSTANT: ``CONFIGURE_MEMORY_OVERHEAD`` DATA TYPE: Unsigned integer (``size_t``). RANGE: Zero or positive. DEFAULT VALUE: The default value is 0. DESCRIPTION: This parameter is set to the number of kilobytes the application wishes to add to the requirements calculated by ````. NOTES: This configuration parameter should only be used when it is suspected that a bug in ```` has resulted in an underestimation. Typically the memory allocation will be too low when an application does not account for all message queue buffers or task stacks. .. index:: CONFIGURE_MESSAGE_BUFFER_MEMORY .. index:: configure message queue buffer memory .. index:: CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE .. index:: memory for a single message queue's buffers .. _CONFIGURE_MESSAGE_BUFFER_MEMORY: CONFIGURE_MESSAGE_BUFFER_MEMORY ------------------------------- CONSTANT: ``CONFIGURE_MESSAGE_BUFFER_MEMORY`` DATA TYPE: integer summation macro RANGE: undefined (zero) or calculation resulting in a positive integer DEFAULT VALUE: The default value is zero. DESCRIPTION: The value of this configuration option defines the number of bytes resereved for message queue buffers in the RTEMS Workspace. NOTES: The configuration options :ref:`CONFIGURE_MAXIMUM_MESSAGE_QUEUES` and :ref:`CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES` define only how many message queues can be created by the application. The memory for the message buffers is configured by this option. For each message queue you have to reserve some memory for the message buffers. The size dependes on the maximum number of pending messages and the maximum size of the messages of a message queue. Use the ``CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE()`` macro to specify the message buffer memory for each message queue and sum them up to define the value for ``CONFIGURE_MAXIMUM_MESSAGE_QUEUES``. The interface for the ``CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE()`` help macro is as follows: .. code-block:: c CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE( max_messages, max_msg_size ) Where ``max_messages`` is the maximum number of pending messages and ``max_msg_size`` is the maximum size in bytes of the messages of the corresponding message queue. Both parameters shall be compile time constants. Not using this help macro (e.g. just using ``max_messages * max_msg_size``) may result in an underestimate of the RTEMS Workspace size. The following example illustrates how the `CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE()` help macro can be used to assist in calculating the message buffer memory required. In this example, there are two message queues used in this application. The first message queue has a maximum of 24 pending messages with the message structure defined by the type ``one_message_type``. The other message queue has a maximum of 500 pending messages with the message structure defined by the type ``other_message_type``. .. code-block:: c #define CONFIGURE_MESSAGE_BUFFER_MEMORY ( \ CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE( \ 24, \ sizeof( one_message_type ) \ ) \ + CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE( \ 500, \ sizeof( other_message_type ) \ ) \ ) .. index:: CONFIGURE_MICROSECONDS_PER_TICK .. index:: tick quantum .. _CONFIGURE_MICROSECONDS_PER_TICK: CONFIGURE_MICROSECONDS_PER_TICK ------------------------------- CONSTANT: ``CONFIGURE_MICROSECONDS_PER_TICK`` DATA TYPE: Unsigned integer (``uint32_t``). RANGE: Positive. DEFAULT VALUE: This is not defined by default. When not defined, the clock tick quantum is configured to be 10,000 microseconds which is ten (10) milliseconds. DESCRIPTION: This constant is used to specify the length of time between clock ticks. When the clock tick quantum value is too low, the system will spend so much time processing clock ticks that it does not have processing time available to perform application work. In this case, the system will become unresponsive. The lowest practical time quantum varies widely based upon the speed of the target hardware and the architectural overhead associated with interrupts. In general terms, you do not want to configure it lower than is needed for the application. The clock tick quantum should be selected such that it all blocking and delay times in the application are evenly divisible by it. Otherwise, rounding errors will be introduced which may negatively impact the application. NOTES: This configuration parameter has no impact if the Clock Tick Device driver is not configured. There may be BSP specific limits on the resolution or maximum value of a clock tick quantum. .. index:: CONFIGURE_MINIMUM_TASK_STACK_SIZE .. index:: minimum task stack size .. _CONFIGURE_MINIMUM_TASK_STACK_SIZE: CONFIGURE_MINIMUM_TASK_STACK_SIZE --------------------------------- CONSTANT: ``CONFIGURE_MINIMUM_TASK_STACK_SIZE`` DATA TYPE: Unsigned integer (``uint32_t``). RANGE: Positive. DEFAULT VALUE: The default value is architecture-specific. DESCRIPTION: This configuration parameter defines the minimum stack size in bytes for every user task or thread in the system. NOTES: Adjusting this parameter should be done with caution. Examining the actual stack usage using the stack checker usage reporting facility is recommended (see also :ref:`CONFIGURE_STACK_CHECKER_ENABLED `). This parameter can be used to lower the minimum from that recommended. This can be used in low memory systems to reduce memory consumption for stacks. However, this must be done with caution as it could increase the possibility of a blown task stack. This parameter can be used to increase the minimum from that recommended. This can be used in higher memory systems to reduce the risk of stack overflow without performing analysis on actual consumption. By default, this configuration parameter defines also the minimum stack size of POSIX threads. This can be changed with the :ref:`CONFIGURE_MINIMUM_POSIX_THREAD_STACK_SIZE ` configuration option. In releases before RTEMS 5.1 the ``CONFIGURE_MINIMUM_TASK_STACK_SIZE`` was used to define the default value of :ref:`CONFIGURE_INTERRUPT_STACK_SIZE `. .. index:: CONFIGURE_STACK_CHECKER_ENABLED .. _CONFIGURE_STACK_CHECKER_ENABLED: CONFIGURE_STACK_CHECKER_ENABLED ------------------------------- CONSTANT: ``CONFIGURE_STACK_CHECKER_ENABLED`` DATA TYPE: Boolean feature macro. RANGE: Defined or undefined. DEFAULT VALUE: This is not defined by default, and thus stack checking is disabled. DESCRIPTION: This configuration parameter is defined when the application wishes to enable run-time stack bounds checking. NOTES: In 4.9 and older, this configuration parameter was named ``STACK_CHECKER_ON``. This increases the time required to create tasks as well as adding overhead to each context switch. .. index:: CONFIGURE_TICKS_PER_TIMESLICE .. index:: ticks per timeslice .. _CONFIGURE_TICKS_PER_TIMESLICE: CONFIGURE_TICKS_PER_TIMESLICE ----------------------------- CONSTANT: ``CONFIGURE_TICKS_PER_TIMESLICE`` DATA TYPE: Unsigned integer (``uint32_t``). RANGE: Positive. DEFAULT VALUE: The default value is 50. DESCRIPTION: This configuration parameter specifies the length of the timeslice quantum in ticks for each task. NOTES: This configuration parameter has no impact if the Clock Tick Device driver is not configured. .. index:: CONFIGURE_UNIFIED_WORK_AREAS .. index:: unified work areas .. index:: separate work areas .. index:: RTEMS Workspace .. index:: C Program Heap .. _CONFIGURE_UNIFIED_WORK_AREAS: CONFIGURE_UNIFIED_WORK_AREAS ---------------------------- CONSTANT: ``CONFIGURE_UNIFIED_WORK_AREAS`` DATA TYPE: Boolean feature macro. RANGE: Defined or undefined. DEFAULT VALUE: This is not defined by default, which specifies that the C Program Heap and the RTEMS Workspace will be separate. DESCRIPTION: When defined, the C Program Heap and the RTEMS Workspace will be one pool of memory. When not defined, there will be separate memory pools for the RTEMS Workspace and C Program Heap. NOTES: Having separate pools does have some advantages in the event a task blows a stack or writes outside its memory area. However, in low memory systems the overhead of the two pools plus the potential for unused memory in either pool is very undesirable. In high memory environments, this is desirable when you want to use the RTEMS "unlimited" objects option. You will be able to create objects until you run out of all available memory rather then just until you run out of RTEMS Workspace. .. _CONFIGURE_UNLIMITED_ALLOCATION_SIZE: CONFIGURE_UNLIMITED_ALLOCATION_SIZE ----------------------------------- CONSTANT: ``CONFIGURE_UNLIMITED_ALLOCATION_SIZE`` DATA TYPE: Unsigned integer (``uint32_t``). RANGE: Positive. DEFAULT VALUE: If not defined and ``CONFIGURE_UNLIMITED_OBJECTS`` is defined, the default value is eight (8). DESCRIPTION: ``CONFIGURE_UNLIMITED_ALLOCATION_SIZE`` provides an allocation size to use for ``rtems_resource_unlimited`` when using ``CONFIGURE_UNLIMITED_OBJECTS``. NOTES: By allowing users to declare all resources as being unlimited the user can avoid identifying and limiting the resources used. ``CONFIGURE_UNLIMITED_OBJECTS`` does not support varying the allocation sizes for different objects; users who want that much control can define the ``rtems_resource_unlimited`` macros themselves. .. index:: CONFIGURE_UNLIMITED_OBJECTS .. _CONFIGURE_UNLIMITED_OBJECTS: CONFIGURE_UNLIMITED_OBJECTS --------------------------- CONSTANT: ``CONFIGURE_UNLIMITED_OBJECTS`` DATA TYPE: Boolean feature macro. RANGE: Defined or undefined. DEFAULT VALUE: This is not defined by default. DESCRIPTION: ``CONFIGURE_UNLIMITED_OBJECTS`` enables ``rtems_resource_unlimited`` mode for Classic API and POSIX API objects that do not already have a specific maximum limit defined. NOTES: When using unlimited objects, it is common practice to also specify ``CONFIGURE_UNIFIED_WORK_AREAS`` so the system operates with a single pool of memory for both RTEMS and application memory allocations. .. index:: CONFIGURE_VERBOSE_SYSTEM_INITIALIZATION .. _CONFIGURE_VERBOSE_SYSTEM_INITIALIZATION: CONFIGURE_VERBOSE_SYSTEM_INITIALIZATION --------------------------------------- CONSTANT: ``CONFIGURE_VERBOSE_SYSTEM_INITIALIZATION`` DATA TYPE: Boolean feature macro. RANGE: Defined or undefined. DEFAULT VALUE: This is not defined by default, and thus the system initialization is quiet. DESCRIPTION: This configuration option enables to print some information during system initialization. NOTES: You may use this feature to debug system initialization issues. The printk() function is used to print the information. .. index:: CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY .. index:: clear C Program Heap .. index:: clear RTEMS Workspace .. index:: zero C Program Heap .. index:: zero RTEMS Workspace .. _CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY: CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY -------------------------------------- CONSTANT: ``CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY`` DATA TYPE: Boolean feature macro. RANGE: Defined or undefined. DEFAULT VALUE: This is not defined by default. The default is *NOT* to zero out the RTEMS Workspace or C Program Heap. DESCRIPTION: This macro indicates whether RTEMS should zero the RTEMS Workspace and C Program Heap as part of its initialization. If defined, the memory regions are zeroed. Otherwise, they are not. NOTES: Zeroing memory can add significantly to system boot time. It is not necessary for RTEMS but is often assumed by support libraries. In case :ref:`CONFIGURE_DIRTY_MEMORY` is also defined, then the memory is first dirtied and then zeroed.