@c COPYRIGHT (c) 1988-2011. @c On-Line Applications Research Corporation (OAR). @c All rights reserved. @c @c $Id$ @c @c The following macros from confdefs.h have not been discussed in this @c chapter: @c @c CONFIGURE_NEWLIB_EXTENSION - probably not needed @c @c In addition, there should be examples of defining your own @c Device Driver Table, Init task table, etc. @c @c Regardless, this is a big step up. :) @c @chapter Configuring a System @section Introduction RTEMS must be configured for an application. This configuration information encompasses a variety of information including the length of each clock tick, the maximum number of each RTEMS object that can be created, the application initialization tasks, the task scheduling algorithm to be used, and the device drivers in the application. This information is placed in data structures that are given to RTEMS at system initialization time. This chapter details the format of these data structures as well as a simpler mechanism to automate the generation of these structures. @ifset is-Ada System configuration is ALWAYS done from C. When developing an Ada application, the user is responsible for creating at least one C file which contains the Ada run-time initialization and the RTEMS System Configuration. There is no Ada binding for RTEMS System Configuration information. Thus all examples and data structures shown in this chapter are in C. @end ifset @section Automatic Generation of System Configuration @cindex confdefs.h @findex confdefs.h RTEMS provides the @code{rtems/confdefs.h} C language header file that based on the setting of a variety of macros can automatically produce nearly all of the configuration tables required by an RTEMS application. Rather than building the individual tables by hand, the application simply specifies the values for the configuration parameters it wishes to set. In the following example, the configuration information for a simple system with a message queue and a time slice of 50 milliseconds is configured: @example @group #define CONFIGURE_APPLICATION_NEEDS_CONSOLE_DRIVER #define CONFIGURE_APPLICATION_NEEDS_CLOCK_DRIVER #define CONFIGURE_MICROSECONDS_PER_TICK 1000 /* 1 millisecond */ #define CONFIGURE_TICKS_PER_TIMESLICE 50 /* 50 milliseconds */ #define CONFIGURE_MAXIMUM_TASKS 4 #define CONFIGURE_RTEMS_INIT_TASKS_TABLE @end group @end example This system will begin execution with the single initialization task named @code{Init}. It will be configured to have both a console device driver (for standard I/O) and a clock tick device driver. For each configuration parameter in the configuration tables, the macro corresponding to that field is discussed. Most systems can be easily configured using the @code{rtems/confdefs.h} mechanism. The @code{CONFIGURE_INIT} constant must be defined in order to make @code{rtems/confdefs.h} instantiate the configuration data structures. This can only be defined in one source file per application that includes @code{rtems/confdefs.h} or the symbol table will be instantiated multiple times and linking errors produced. The user should be aware that the defaults are intentionally set as low as possible. By default, no application resources are configured. The @code{rtems/confdefs.h} file ensures that at least one application tasks or thread is configured and that at least one of the initialization task/thread tables is configured. The @code{rtems/confdefs.h} file estimates the amount of memory required for the RTEMS Executive Workspace. This estimate is only as accurate as the information given to @code{rtems/confdefs.h} and may be either too high or too low for a variety of reasons. Some of the reasons that @code{rtems/confdefs.h} may reserve too much memory for RTEMS are: @itemize @bullet @item All tasks/threads are assumed to be floating point. @end itemize Conversely, there are many more reasons, the resource estimate could be too low: @itemize @bullet @item Task/thread stacks greater than minimum size must be accounted for explicitly by developer. @item Memory for messages is not included. @item Device driver requirements are not included. @item Network stack requirements are not included. @item Requirements for add-on libraries are not included. @end itemize In general, @code{rtems/confdefs.h} is very accurate when given enough information. However, it is quite easy to use a library and not account for its resources. The following subsection list all of the constants which can be set by the user. @subsection Library Support Definitions This section defines the file system and IO library related configuration parameters supported by @code{rtems/confdefs.h}. @itemize @bullet @findex CONFIGURE_MALLOC_STATISTICS @item @code{CONFIGURE_MALLOC_STATISTICS} is defined when the application wishes to enable the gathering of more detailed statistics on the C Malloc Family of routines. @findex CONFIGURE_MALLOC_BSP_SUPPORTS_SBRK @item @code{CONFIGURE_MALLOC_BSP_SUPPORTS_SBRK} is defined by a BSP to indicate that it does not allocate all available memory to the C Program Heap used by the Malloc Family of routines. If defined, when @code{malloc()} is unable to allocate memory, it will call the BSP supplied @code{sbrk()} to obtain more memory. @findex CONFIGURE_LIBIO_MAXIMUM_FILE_DESCRIPTORS @item @code{CONFIGURE_LIBIO_MAXIMUM_FILE_DESCRIPTORS} is set to the maximum number of files that can be concurrently open. Libio requires a Classic RTEMS semaphore for each file descriptor as well as one global one. The default value is 3 file descriptors which is enough to support standard input, output, and error output. @findex CONFIGURE_TERMIOS_DISABLED @item @code{CONFIGURE_TERMIOS_DISABLED} is defined if the software implementing POSIX termios functionality is not going to be used by this application. By default, this is not defined and resources are reserved for the termios functionality. @findex CONFIGURE_NUMBER_OF_TERMIOS_PORTS @item @code{CONFIGURE_NUMBER_OF_TERMIOS_PORTS} is set to the number of ports using the termios functionality. Each concurrently active termios port requires resources. By default, this is set to 1 so a console port can be used. @findex CONFIGURE_HAS_OWN_MOUNT_TABLE @item @code{CONFIGURE_HAS_OWN_MOUNT_TABLE} is defined when the application provides their own filesystem mount table. The mount table is an array of @code{rtems_filesystem_mount_table_t} entries pointed to by the global variable @code{rtems_filesystem_mount_table}. The number of entries in this table is in an integer variable named @code{rtems_filesystem_mount_table_t}. @findex CONFIGURE_USE_IMFS_AS_BASE_FILESYSTEM @item @code{CONFIGURE_USE_IMFS_AS_BASE_FILESYSTEM} is defined if the application wishes to use the full functionality IMFS. By default, the miniIMFS is used. The miniIMFS is a minimal functionality subset of the In-Memory FileSystem (IMFS). The miniIMFS is comparable in functionality to the pseudo-filesystem name space provided before RTEMS release 4.5.0. The miniIMFS supports only directories and device nodes and is smaller in executable code size than the full IMFS. @findex CONFIGURE_USE_DEVFS_AS_BASE_FILESYSTEM @item @code{CONFIGURE_USE_DEVFS_AS_BASE_FILESYSTEM} is defined if the application wishes to use the device-only filesytem. The device-only filesystem supports only device nodes and is smaller in executable code size than the full IMFS and miniIMFS. @findex CONFIGURE_APPLICATION_DISABLE_FILESYSTEM @item @code{CONFIGURE_APPLICATION_DISABLE_FILESYSTEM} is defined if the application dose not intend to use any kind of filesystem supports(including printf family). @findex CONFIGURE_STACK_CHECKER_ENABLED @item @code{CONFIGURED_STACK_CHECKER_ENABLED} is defined when the application wishes to enable run-time stack bounds checking. This increases the time required to create tasks as well as adding overhead to each context switch. By default, this is not defined and thus stack checking is disabled. NOTE: In 4.9 and older, this was named @code{STACK_CHECKER_ON} @end itemize @subsection Basic System Information This section defines the general system configuration parameters supported by @code{rtems/confdefs.h}. @itemize @bullet @findex CONFIGURE_HAS_OWN_CONFIGURATION_TABLE @item @code{CONFIGURE_HAS_OWN_CONFIGURATION_TABLE} should only be defined if the application is providing their own complete set of configuration tables. @findex CONFIGURE_EXECUTIVE_RAM_WORK_AREA @item @code{CONFIGURE_EXECUTIVE_RAM_WORK_AREA} is the base address of the RTEMS RAM Workspace. By default, this value is NULL indicating that the BSP is to determine the location of the RTEMS RAM Workspace. @findex CONFIGURE_UNIFIED_WORK_AREAS @item @code{CONFIGURE_UNIFIED_WORK_AREAS} configures RTEMS to use a single memory pool for the RTEMS Workspace and C Program Heap. If not defined, there will be separate memory pools for the RTEMS Workspace and C Program Heap. 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. @item @code{CONFIGURE_MICROSECONDS_PER_TICK} is the length of time between clock ticks. By default, this is set to 10000 microseconds. @findex CONFIGURE_TICKS_PER_TIMESLICE @item @code{CONFIGURE_TICKS_PER_TIMESLICE} is the length of the timeslice quantum in ticks for each task. By default, this is 50. @findex CONFIGURE_MAXIMUM_PRIORITY @item @code{CONFIGURE_MAXIMUM_PRIORITY} is the maximum numeric priority of any task in the system and one less that the number of priority levels in the system. The numerically greatest priority is the logically lowest priority in the system and will thus be used by the IDLE task. 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. Reducing the number of priorities in the system reduces the amount of memory allocated from the RTEMS Workspace. By default, RTEMS supports 256 priority levels ranging from 0 to 255 so the default value for this field is 255. @findex CONFIGURE_MICROSECONDS_PER_TICK @fnindex CONFIGURE_MINIMUM_STACK_SIZE @item @code{CONFIGURE_MINIMUM_STACK_SIZE} is set to the number of bytes the application wants the minimum stack size to be for every task or thread in the system. By default, this is set to the recommended minimum stack size for this processor. @fnindex CONFIGURE_INTERRUPT_STACK_SIZE @item @code{CONFIGURE_INTERRUPT_STACK_SIZE} is set to the size of the interrupt stack. The interrupt stack size is usually set by the BSP but since this memory may be allocated from the RTEMS Ram Workspace, it must be accounted for. The default for this field is the configured minimum stack size. [NOTE: In some BSPs, changing this constant does NOT change the size of the interrupt stack, only the amount of memory reserved for it.] If not specified, the interrupt stack will be of minimum size. The default value is the configured minimum stack size. @findex CONFIGURE_TASK_STACK_ALLOCATOR @item @code{CONFIGURE_TASK_STACK_ALLOCATOR} may point to a user provided routine to allocate task stacks. The default value for this field is NULL which indicates that task stacks will be allocated from the RTEMS Workspace. @findex CONFIGURE_TASK_STACK_DEALLOCATOR @item @code{CONFIGURE_TASK_STACK_DEALLOCATOR} may point to a user provided routine to free task stacks. The default value for this field is NULL which indicates that task stacks will be allocated from the RTEMS Workspace. @findex CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY @item @code{CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY} indicates whether RTEMS should zero the RTEMS Workspace and C Program Heap as part of its initialization. If set to TRUE, the Workspace is zeroed. Otherwise, it is not. Unless overridden by the BSP, the default value for this field is FALSE. @findex CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE @item @code{CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE} is a helper macro which is used to assist in computing the total amount of memory required for message buffers. Each message queue will have its own configuration with maximum message size and maximum number of pending messages. The interface for this macro is as follows: @example CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE(max_messages, size_per) @end example Where @code{max_messages} is the maximum number of pending messages and @code{size_per} is the size in bytes of the user message. @findex CONFIGURE_MESSAGE_BUFFER_MEMORY @item @code{CONFIGURE_MESSAGE_BUFFER_MEMORY} is set to the number of bytes the application requires to be reserved for pending message queue buffers. This value should include memory for all buffers across all APIs. The default value is 0. The following illustrates how the help macro @code{CONFIGURE_MESSAGE_BUFFERS_FOR_QUEUE} 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 maximum of 24 pending messages with the message structure defined by the type @code{one_message_type}. The other message queue has maximum of 500 pending messages with the message structure defined by the type @code{other_message_type}. @example #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) \ ) @end example @findex CONFIGURE_MEMORY_OVERHEAD @item @code{CONFIGURE_MEMORY_OVERHEAD} is set to the number of kilobytes the application wishes to add to the requirements calculated by @code{rtems/confdefs.h}. The default value is 0. @findex CONFIGURE_EXTRA_TASK_STACKS @item @code{CONFIGURE_EXTRA_TASK_STACKS} is set to the number of bytes the applications wishes to add to the task stack requirements calculated by @code{rtems/confdefs.h}. This parameter is very important. If the application creates tasks with stacks larger then the minimum, then that memory is NOT accounted for by @code{rtems/confdefs.h}. The default value is 0. @end itemize NOTE: The required size of the Executive RAM Work Area is calculated automatically when using the @code{rtems/confdefs.h} mechanism. @c @c @c @subsection Idle Task Configuration This section defines the IDLE task related configuration parameters supported by @code{rtems/confdefs.h}. @itemize @bullet @fnindex CONFIGURE_IDLE_TASK_BODY @item @code{CONFIGURE_IDLE_TASK_BODY} is set to the method name corresponding to the application specific IDLE thread body. If not specified, the BSP or RTEMS default IDLE thread body will be used. The default value is NULL. @fnindex CONFIGURE_IDLE_TASK_STACK_SIZE @item @code{CONFIGURE_IDLE_TASK_STACK_SIZE} is set to the desired stack size for the IDLE task. If not specified, the IDLE task will have a stack of minimum size. The default value is the configured minimum stack size. @fnindex CONFIGURE_IDLE_TASK_INITIALIZES_APPLICATION @item @code{CONFIGURE_IDLE_TASK_INITIALIZES_APPLICATION} is set to indicate that the user has configured @b{NO} user initialization tasks or threads and that the user provided IDLE task will perform application initialization and then transform itself into an IDLE task. If you use this option be careful, the user IDLE task @b{CANNOT} block at all during the initialization sequence. Further, once application initialization is complete, it must make itself preemptible and enter an IDLE body loop. By default, this is not the mode of operation and the user is assumed to provide one or more initialization tasks. @end itemize @c @c @c @subsection Scheduler Algorithm Configuration This section defines the configuration parameters related to selecting a scheduling algorithm for an application. For the schedulers built into RTEMS, the configuration is straightforward. All that is required is to define the configuration macro which specifies which scheduler you want for in your application. The currently available schedulers are: @itemize @bullet @findex CONFIGURE_SCHEDULER_PRIORITY @item Deterministic Priority Scheduler - This is the default scheduler in RTEMS for single core applications and is designed for predictable performance under the highest loads. It can block or unblock a thread in a constant amount of time. This scheduler requires a variable amount of memory based upon the number of priorities configured in the system. This scheduler may be explicitly selected by defining @code{CONFIGURE_SCHEDULER_PRIORITY}. @findex CONFIGURE_SCHEDULER_SIMPLE @item Simple Priority Scheduler - This is an alternative scheduler in RTEMS. It is designed to provide the same task scheduling behaviour as the Deterministic Priority Scheduler while being simpler in implementation and uses less memory for data management. It maintains a single sorted list of all ready threads. Thus blocking or unblocking a thread is not a constant time operation with this scheduler. This scheduler is appropriate for use in small systems where RAM is limited. This scheduler may be explicitly selected by defining @code{CONFIGURE_SCHEDULER_SIMPLE}. @findex CONFIGURE_SCHEDULER_SIMPLE_SMP @item Simple SMP Priority Scheduler - This scheduler is derived from the Simple Priority Scheduler but is capable of scheduling threads across multiple cores. It is designed to provide the same task scheduling behaviour as the Deterministic Priority Scheduler while distributing threads across multiple cores. Being based upon the Simple Priority Scheduler, it also maintains a single sorted list of all ready threads. Thus blocking or unblocking a thread is not a constant time operation with this scheduler. In addition, when allocating threads to cores, the algorithm is not constant time. This algorithm was not designed with efficiency as a primary design goal. Its primary design goal was to provide an SMP-aware scheduling algorithm that is simple to understand. This scheduler is currently the default in SMP configurations and is only selected when @code{CONFIGURE_SMP_APPLICATION} is defined. In a configuration with SMP enabled at configure time, it may be explicitly selected by defining @code{CONFIGURE_SCHEDULER_SIMPLE_SMP}. @end itemize The pluggable scheduler interface was added after the 4.10 release series so there are not a lot of options at this point. We anticipate a lower memory, non-deterministic priority scheduler suitable for use in small systems and an Earliest Deadline First Scheduler (EDF) to arrive in the future. The pluggable scheduler interface enables the user to provide their own scheduling algorithm. If you choose to do this, you must define multiple configuration macros. @findex CONFIGURE_SCHEDULER_USER First, you must define @code{CONFIGURE_SCHEDULER_USER} to indicate the application provides its own scheduling algorithm. If @code{CONFIGURE_SCHEDULER_USER} is defined then the following additional macros must be defined: @itemize @bullet @item @code{CONFIGURE_SCHEDULER_USER_ENTRY_POINTS} must be defined with the set of methods which implement this scheduler. @item @code{CONFIGURE_MEMORY_FOR_SCHEDULER} must be defined with the amount of memory required as a base amount for the scheduler. @item @code{CONFIGURE_MEMORY_PER_TASK_FOR_SCHEDULER(_tasks)} must be defined as a formula which computes the amount of memory required based upon the number of tasks configured. @end itemize At this time, the mechanics and requirements for writing a new scheduler are evolving and not fully documented. It is recommended that you look at the existing Deterministic Priority Scheduler in @code{cpukit/score/src/schedulerpriority*.c} for guidance. For guidance on the configuration macros, please examine @code{cpukit/sapi/include/confdefs.h} for how these are defined for the Deterministic Priority Scheduler. @c @c @c @subsection SMP Specific Configuration Parameters When RTEMS is configured to support SMP target systems, there are other configuration parameters which apply. @itemize @bullet @findex CONFIGURE_SMP_APPLICATION @item @code{CONFIGURE_SMP_APPLICATION} must be defined if the application is to make use of multiple CPU cores in an SMP target system. @item @code{CONFIGURE_SMP_MAXIMUM_PROCESSORS} must be set to the number of CPU cores in the SMP configuration. If there are more cores available than configured, the rest will be ignored. @end itemize @c @c @c @subsection Device Driver Table This section defines the configuration parameters related to the automatic generation of a Device Driver Table. As @code{rtems/confdefs.h} only is aware of a small set of standard device drivers, the generated Device Driver Table is suitable for simple applications with no custom device drivers. @itemize @bullet @findex CONFIGURE_HAS_OWN_DEVICE_DRIVER_TABLE @item @code{CONFIGURE_HAS_OWN_DEVICE_DRIVER_TABLE} is defined if the application wishes to provide their own Device Driver Table. The table generated is an array of @code{rtems_driver_address_table} entries named @code{Device_drivers}. By default, this is not defined indicating the @code{rtems/confdefs.h} is providing the device driver table. @findex CONFIGURE_MAXIMUM_DRIVERS @item @code{CONFIGURE_MAXIMUM_DRIVERS} is defined as the number of device drivers per node. By default, this is set to 10. @findex CONFIGURE_MAXIMUM_DEVICES @item @code{CONFIGURE_MAXIMUM_DEVICES} is defined to the number of individual devices that may be registered in the system. By default, this is set to 4. @findex CONFIGURE_APPLICATION_NEEDS_CONSOLE_DRIVER @item @code{CONFIGURE_APPLICATION_NEEDS_CONSOLE_DRIVER} is defined if the application wishes to include the Console Device Driver. This device driver is responsible for providing standard input and output using "/dev/console". By default, this is not defined. @findex CONFIGURE_APPLICATION_NEEDS_CLOCK_DRIVER @item @code{CONFIGURE_APPLICATION_NEEDS_CLOCK_DRIVER} is defined if the application wishes to include the Clock Device Driver. This device driver is responsible for providing a regular interrupt which invokes the @code{rtems_clock_tick} directive. By default, this is not defined. @findex CONFIGURE_APPLICATION_NEEDS_TIMER_DRIVER @item @code{CONFIGURE_APPLICATION_NEEDS_TIMER_DRIVER} is defined if the application wishes to include the Timer Driver. This device driver is used to benchmark execution times by the RTEMS Timing Test Suites. By default, this is not defined. @findex CONFIGURE_APPLICATION_DOES_NOT_NEED_CLOCK_DRIVER @item @code{CONFIGURE_APPLICATION_DOES_NOT_NEED_CLOCK_DRIVER} is defined when the application does @b{NOT} want the Clock Device Driver and is @b{NOT} using the Timer Driver. The inclusion or exclusion of the Clock Driver must be explicit in typical user applications. This is intended to prevent the common user error of using the Hello World example as the baseline for an application and leaving out a clock tick source. @findex CONFIGURE_APPLICATION_NEEDS_RTC_DRIVER @item @code{CONFIGURE_APPLICATION_NEEDS_RTC_DRIVER} is defined if the application wishes to include the Real-Time Clock Driver. By default, this is not defined. @findex CONFIGURE_APPLICATION_NEEDS_WATCHDOG_DRIVER @item @code{CONFIGURE_APPLICATION_NEEDS_WATCHDOG_DRIVER} is defined if the application wishes to include the Watchdog Driver. By default, this is not defined. @findex CONFIGURE_APPLICATION_NEEDS_FRAME_BUFFER_DRIVER @item @code{CONFIGURE_APPLICATION_NEEDS_FRAME_BUFFER_DRIVER} is defined if the application wishes to include the BSP's Frame Buffer Device Driver. Most BSPs do not provide a Frame Buffer Device Driver. If this is defined and the BSP does not have this device driver, then the user will get a link time error for an undefined symbol. By default, this is not defined. @findex CONFIGURE_APPLICATION_NEEDS_STUB_DRIVER @item @code{CONFIGURE_APPLICATION_NEEDS_STUB_DRIVER} is defined if the application wishes to include the Stub Device Driver. This device driver simply provides entry points that return successful and is primarily a test fixture. By default, this is not defined. @findex CONFIGURE_BSP_PREREQUISITE_DRIVERS @item @code{CONFIGURE_BSP_PREREQUISITE_DRIVERS} is defined if the BSP has device drivers it needs to include in the Device Driver Table. This should be defined to the set of device driver entries that will be placed in the table at the @b{FRONT} of the Device Driver Table and initialized before any other drivers @b{INCLUDING} any application prerequisite drivers. By default,this is not defined. @findex CONFIGURE_APPLICATION_PREREQUISITE_DRIVERS @item @code{CONFIGURE_APPLICATION_PREREQUISITE_DRIVERS} is defined if the application has device drivers it needs to include in the Device Driver Table. This should be defined to the set of device driver entries that will be placed in the table at the @b{FRONT} of the Device Driver Table and initialized before any other drivers @b{EXCEPT} any BSP prerequisite drivers. By default,this is not defined. @findex CONFIGURE_APPLICATION_EXTRA_DRIVERS @item @code{CONFIGURE_APPLICATION_EXTRA_DRIVERS} is defined if the application has device drivers it needs to include in the Device Driver Table. This should be defined to the set of device driver entries that will be placed in the table at the @b{END} of the Device Driver Table. By default,this is not defined. @end itemize @subsection Multiprocessing Configuration This section defines the multiprocessing related system configuration parameters supported by @code{rtems/confdefs.h}. This class of Configuration Constants are only applicable if @code{CONFIGURE_MP_APPLICATION} is defined. @itemize @bullet @findex CONFIGURE_HAS_OWN_MULTIPROCESSING_TABLE @item @code{CONFIGURE_HAS_OWN_MULTIPROCESSING_TABLE} is defined if the application wishes to provide their own Multiprocessing Configuration Table. The generated table is named @code{Multiprocessing_configuration}. By default, this is not defined. @findex CONFIGURE_MP_NODE_NUMBER @item @code{CONFIGURE_MP_NODE_NUMBER} is the node number of this node in a multiprocessor system. The default node number is @code{NODE_NUMBER} which is set directly in RTEMS test Makefiles. @findex CONFIGURE_MP_MAXIMUM_NODES @item @code{CONFIGURE_MP_MAXIMUM_NODES} is the maximum number of nodes in a multiprocessor system. The default is 2. @findex CONFIGURE_MP_MAXIMUM_GLOBAL_OBJECTS @item @code{CONFIGURE_MP_MAXIMUM_GLOBAL_OBJECTS} is the maximum number of concurrently active global objects in a multiprocessor system. The default is 32. @findex CONFIGURE_MP_MAXIMUM_PROXIES @item @code{CONFIGURE_MP_MAXIMUM_PROXIES} is the maximum number of concurrently active thread/task proxies in a multiprocessor system. The default is 32. @findex CONFIGURE_MP_MPCI_TABLE_POINTER @item @code{CONFIGURE_MP_MPCI_TABLE_POINTER} is the pointer to the MPCI Configuration Table. The default value of this field is @code{&MPCI_table}. @end itemize @subsection Classic API Configuration This section defines the Classic API related system configuration parameters supported by @code{rtems/confdefs.h}. @itemize @bullet @findex CONFIGURE_MAXIMUM_TASKS @item @code{CONFIGURE_MAXIMUM_TASKS} is the maximum number of Classic API tasks that can be concurrently active. The default for this field is 0. @findex CONFIGURE_DISABLE_CLASSIC_API_NOTEPADS @item @code{CONFIGURE_DISABLE_CLASSIC_API_NOTEPADS} should be defined if the user does not want to have support for Classic API Notepads in their application. By default, this is not defined and Classic API Notepads are supported. @findex CONFIGURE_MAXIMUM_TIMERS @item @code{CONFIGURE_MAXIMUM_TIMERS} is the maximum number of Classic API timers that can be concurrently active. The default for this field is 0. @findex CONFIGURE_MAXIMUM_SEMAPHORES @item @code{CONFIGURE_MAXIMUM_SEMAPHORES} is the maximum number of Classic API semaphores that can be concurrently active. The default for this field is 0. @findex CONFIGURE_MAXIMUM_MESSAGE_QUEUES @item @code{CONFIGURE_MAXIMUM_MESSAGE_QUEUES} is the maximum number of Classic API message queues that can be concurrently active. The default for this field is 0. @findex CONFIGURE_MAXIMUM_PARTITIONS @item @code{CONFIGURE_MAXIMUM_PARTITIONS} is the maximum number of Classic API partitions that can be concurrently active. The default for this field is 0. @findex CONFIGURE_MAXIMUM_REGIONS @item @code{CONFIGURE_MAXIMUM_REGIONS} is the maximum number of Classic API regions that can be concurrently active. The default for this field is 0. @findex CONFIGURE_MAXIMUM_PORTS @item @code{CONFIGURE_MAXIMUM_PORTS} is the maximum number of Classic API ports that can be concurrently active. The default for this field is 0. @findex CONFIGURE_MAXIMUM_PERIODS @item @code{CONFIGURE_MAXIMUM_PERIODS} is the maximum number of Classic API rate monotonic periods that can be concurrently active. The default for this field is 0. @findex CONFIGURE_MAXIMUM_USER_EXTENSIONS @item @code{CONFIGURE_MAXIMUM_USER_EXTENSIONS} is the maximum number of Classic API user extensions that can be concurrently active. The default for this field is 0. @end itemize @subsection Classic API Initialization Tasks Table Configuration The @code{rtems/confdefs.h} configuration system can automatically generate an Initialization Tasks Table named @code{Initialization_tasks} with a single entry. The following parameters control the generation of that table. @itemize @bullet @findex CONFIGURE_RTEMS_INIT_TASKS_TABLE @item @code{CONFIGURE_RTEMS_INIT_TASKS_TABLE} is defined if the user wishes to use a Classic RTEMS API Initialization Task Table. The application may choose to use the initialization tasks or threads table from another API. By default, this field is not defined as the user MUST select their own API for initialization tasks. @findex CONFIGURE_HAS_OWN_INIT_TASK_TABLE @item @code{CONFIGURE_HAS_OWN_INIT_TASK_TABLE} is defined if the user wishes to define their own Classic API Initialization Tasks Table. This table should be named @code{Initialization_tasks}. By default, this is not defined. @findex CONFIGURE_INIT_TASK_NAME @item @code{CONFIGURE_INIT_TASK_NAME} is the name of the single initialization task defined by the Classic API Initialization Tasks Table. By default the value is @code{rtems_build_name( 'U', 'I', '1', ' ' )}. @findex CONFIGURE_INIT_TASK_STACK_SIZE @item @code{CONFIGURE_INIT_TASK_STACK_SIZE} is the stack size of the single initialization task defined by the Classic API Initialization Tasks Table. By default value is the configured minimum stack size. @findex CONFIGURE_INIT_TASK_PRIORITY @item @code{CONFIGURE_INIT_TASK_PRIORITY} is the initial priority of the single initialization task defined by the Classic API Initialization Tasks Table. By default the value is 1 which is the highest priority in the Classic API. @findex CONFIGURE_INIT_TASK_ATTRIBUTES @item @code{CONFIGURE_INIT_TASK_ATTRIBUTES} is the task attributes of the single initialization task defined by the Classic API Initialization Tasks Table. By default the value is @code{RTEMS_DEFAULT_ATTRIBUTES}. @findex CONFIGURE_INIT_TASK_ENTRY_POINT @item @code{CONFIGURE_INIT_TASK_ENTRY_POINT} is the entry point (a.k.a. function name) of the single initialization task defined by the Classic API Initialization Tasks Table. By default the value is @code{Init}. @findex CONFIGURE_INIT_TASK_INITIAL_MODES @item @code{CONFIGURE_INIT_TASK_INITIAL_MODES} is the initial execution mode of the single initialization task defined by the Classic API Initialization Tasks Table. By default the value is @code{RTEMS_NO_PREEMPT}. @findex CONFIGURE_INIT_TASK_ARGUMENTS @item @code{CONFIGURE_INIT_TASK_ARGUMENTS} is the task argument of the single initialization task defined by the Classic API Initialization Tasks Table. By default the value is 0. @end itemize @subsection POSIX API Configuration The parameters in this section are used to configure resources for the RTEMS POSIX API. They are only relevant if the POSIX API is enabled at configure time using the @code{--enable-posix} option. @itemize @bullet @findex CONFIGURE_MAXIMUM_POSIX_THREADS @item @code{CONFIGURE_MAXIMUM_POSIX_THREADS} is the maximum number of POSIX API threads that can be concurrently active. The default is 0. @findex CONFIGURE_MAXIMUM_POSIX_MUTEXES @item @code{CONFIGURE_MAXIMUM_POSIX_MUTEXES} is the maximum number of POSIX API mutexes that can be concurrently active. The default is 0. @findex CONFIGURE_MAXIMUM_POSIX_CONDITION_VARIABLES @item @code{CONFIGURE_MAXIMUM_POSIX_CONDITION_VARIABLES} is the maximum number of POSIX API condition variables that can be concurrently active. The default is 0. @findex CONFIGURE_MAXIMUM_POSIX_KEYS @item @code{CONFIGURE_MAXIMUM_POSIX_KEYS} is the maximum number of POSIX API keys that can be concurrently active. The default is 0. @findex CONFIGURE_MAXIMUM_POSIX_TIMERS @item @code{CONFIGURE_MAXIMUM_POSIX_TIMERS} is the maximum number of POSIX API timers that can be concurrently active. The default is 0. @findex CONFIGURE_MAXIMUM_POSIX_QUEUED_SIGNALS @item @code{CONFIGURE_MAXIMUM_POSIX_QUEUED_SIGNALS} is the maximum number of POSIX API queued signals that can be concurrently active. The default is 0. @findex CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES @item @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES} is the maximum number of POSIX API message queues that can be concurrently active. The default is 0. @findex CONFIGURE_MAXIMUM_POSIX_SEMAPHORES @item @code{CONFIGURE_MAXIMUM_POSIX_SEMAPHORES} is the maximum number of POSIX API semaphores that can be concurrently active. The default is 0. @end itemize @subsection POSIX Initialization Threads Table Configuration The @code{rtems/confdefs.h} configuration system can automatically generate a POSIX Initialization Threads Table named @code{POSIX_Initialization_threads} with a single entry. The following parameters control the generation of that table. @itemize @bullet @findex CONFIGURE_POSIX_INIT_THREAD_TABLE @item @code{CONFIGURE_POSIX_INIT_THREAD_TABLE} is defined if the user wishes to use a POSIX API Initialization Threads Table. The application may choose to use the initialization tasks or threads table from another API. By default, this field is not defined as the user MUST select their own API for initialization tasks. @findex CONFIGURE_POSIX_HAS_OWN_INIT_THREAD_TABLE @item @code{CONFIGURE_POSIX_HAS_OWN_INIT_THREAD_TABLE} is defined if the user wishes to define their own POSIX API Initialization Threads Table. This table should be named @code{POSIX_Initialization_threads}. By default, this is not defined. @findex CONFIGURE_POSIX_INIT_THREAD_ENTRY_POINT @item @code{CONFIGURE_POSIX_INIT_THREAD_ENTRY_POINT} is the entry point (a.k.a. function name) of the single initialization thread defined by the POSIX API Initialization Threads Table. By default the value is @code{POSIX_Init}. @findex CONFIGURE_POSIX_INIT_THREAD_STACK_SIZE @item @code{CONFIGURE_POSIX_INIT_THREAD_STACK_SIZE} is the stack size of the single initialization thread defined by the POSIX API Initialization Threads Table. By default value is twice the configured minimum stack size. @end itemize @subsection Ada Tasks This section defines the system configuration parameters supported by @code{rtems/confdefs.h} related to configuring RTEMS to support a task using Ada tasking with GNAT. @itemize @bullet @findex CONFIGURE_GNAT_RTEMS @item @code{CONFIGURE_GNAT_RTEMS} is defined to inform RTEMS that the GNAT Ada run-time is to be used by the application. This configuration parameter is critical as it makes @code{rtems/confdefs.h} configure the resources (mutexes and keys) used implicitly by the GNAT run-time. By default, this parameter is not defined. @findex CONFIGURE_MAXIMUM_ADA_TASKS @item @code{CONFIGURE_MAXIMUM_ADA_TASKS} is the number of Ada tasks that can be concurrently active in the system. By default, when @code{CONFIGURE_GNAT_RTEMS} is defined, this is set to 20. @findex CONFIGURE_MAXIMUM_FAKE_ADA_TASKS @item @code{CONFIGURE_MAXIMUM_FAKE_ADA_TASKS} is the number of "fake" Ada tasks that can be concurrently active in the system. A "fake" Ada task is a non-Ada task that makes calls back into Ada code and thus implicitly uses the Ada run-time. @end itemize @section Configuration Data Structures It is recommended that applications be configured using @code{rtems/confdefs.h} as it is simpler and insulates applications from changes in the underlying data structures. However, it is sometimes important to understand the data structures that are automatically filled in by the configuration parameters. This section describes the primary configuration data structures. @subsection Configuration Table @cindex Configuration Table @cindex RTEMS Configuration Table The RTEMS Configuration Table is used to tailor an application for its specific needs. For example, the user can configure the number of device drivers or which APIs may be used. THe address of the user-defined Configuration Table is passed as an argument to the @code{rtems_initialize_executive} directive, which MUST be the first RTEMS directive called. The RTEMS Configuration Table is defined in the following C structure: @findex rtems_configuration_table @example @group typedef struct @{ void *work_space_start; uintptr_t work_space_size; uint32_t maximum_extensions; uint32_t microseconds_per_tick; uint32_t ticks_per_timeslice; uint32_t scheduler_policy; void (*idle_task)( void ); uint32_t idle_task_stack_size; uint32_t interrupt_stack_size; void * (*stack_allocate_hook)( size_t ); void (*stack_free_hook)( void * ); bool do_zero_of_workspace; uint32_t maximum_drivers; uint32_t number_of_device_drivers; rtems_driver_address_table *Device_driver_table; uint32_t number_of_initial_extensions; rtems_extensions_table *User_extension_table; #if defined(RTEMS_MULTIPROCESSING) rtems_multiprocessing_table *User_multiprocessing_table; #endif rtems_api_configuration_table *RTEMS_api_configuration; posix_api_configuration_table *POSIX_api_configuration; @} rtems_configuration_table; @end group @end example @table @b @item work_space_start is the address of the RTEMS RAM Workspace. This area contains items such as the various object control blocks (TCBs, QCBs, ...) and task stacks. If the address is not aligned on a four-word boundary, then RTEMS will invoke the fatal error handler during @code{rtems_initialize_executive}. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_EXECUTIVE_RAM_WORK_AREA} which defaults to @code{NULL}. Normally, this field should be configured as @code{NULL} as BSPs will assign memory for the RTEMS RAM Workspace as part of system initialization. @item work_space_size is the calculated size of the RTEMS RAM Workspace. The section Sizing the RTEMS RAM Workspace details how to arrive at this number. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_EXECUTIVE_RAM_SIZE} and is calculated based on the other system configuration settings. @item microseconds_per_tick is number of microseconds per clock tick. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MICROSECONDS_PER_TICK}. If not defined by the application, then the @code{CONFIGURE_MICROSECONDS_PER_TICK} macro defaults to 10000 (10 milliseconds). @item ticks_per_timeslice is the number of clock ticks for a timeslice. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_TICKS_PER_TIMESLICE}. @item scheduler_policy is the algorithm to use for task scheduling. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_SCHEDULER_POLICY}. @item idle_task is the address of the optional user provided routine which is used as the system's IDLE task. If this field is not NULL, then the RTEMS default IDLE task is not used. This field may be NULL to indicate that the default IDLE is to be used. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_IDLE_TASK_BODY}. @item idle_task_stack_size is the size of the RTEMS idle task stack in bytes. If this number is less than the configured minimum stack size, then the idle task's stack will be set to the minimum. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_IDLE_TASK_STACK_SIZE}. @item interrupt_stack_size is the size of the RTEMS interrupt stack in bytes. If this number is less than configured minimum stack size, then the interrupt stack will be set to the minimum. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_INTERRUPT_STACK_SIZE}. @item stack_allocate_hook may point to a user provided routine to allocate task stacks. The default is to allocate task stacks from the RTEMS Workspace. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_TASK_STACK_ALLOCATOR}. @item stack_free_hook may point to a user provided routine to free task stacks. The default is to allocate task stacks from the RTEMS Workspace. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_TASK_STACK_DEALLOCATOR}. @item do_zero_of_workspace indicates whether RTEMS should zero the RTEMS Workspace and C Program Heap as part of its initialization. If set to TRUE, the Workspace is zeroed. Otherwise, it is not. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_ZERO_WORKSPACE_AUTOMATICALLY}. @item maximum_drivers is the maximum number of device drivers that can be registered. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_DRIVERS}. @item number_of_device_drivers is the number of device drivers for the system. There should be the same number of entries in the Device Driver Table. If this field is zero, then the @code{User_driver_address_table} entry should be NULL. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field is calculated automatically based on the number of entries in the Device Driver Table. This calculation is based on the assumption that the Device Driver Table is named @code{Device_drivers} and defined in C. This table may be generated automatically for simple applications using only the device drivers that correspond to the following macros: @itemize @bullet @item @code{CONFIGURE_APPLICATION_NEEDS_CONSOLE_DRIVER} @item @code{CONFIGURE_APPLICATION_NEEDS_CLOCK_DRIVER} @item @code{CONFIGURE_APPLICATION_NEEDS_TIMER_DRIVER} @item @code{CONFIGURE_APPLICATION_NEEDS_RTC_DRIVER} @item @code{CONFIGURE_APPLICATION_NEEDS_STUB_DRIVER} @end itemize Note that network device drivers are not configured in the Device Driver Table. @item Device_driver_table is the address of the Device Driver Table. This table contains the entry points for each device driver. If the number_of_device_drivers field is zero, then this entry should be NULL. The format of this table will be discussed below. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the Device Driver Table is assumed to be named @code{Device_drivers} and defined in C. If the application is providing its own Device Driver Table, then the macro @code{CONFIGURE_HAS_OWN_DEVICE_DRIVER_TABLE} must be defined to indicate this and prevent @code{rtems/confdefs.h} from generating the table. @item number_of_initial_extensions is the number of initial user extensions. There should be the same number of entries as in the User_extension_table. If this field is zero, then the User_driver_address_table entry should be NULL. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_NUMBER_OF_INITIAL_EXTENSIONS} which is set automatically by @code{rtems/confdefs.h} based on the size of the User Extensions Table. @item User_extension_table is the address of the User Extension Table. This table contains the entry points for the static set of optional user extensions. If no user extensions are configured, then this entry should be NULL. The format of this table will be discussed below. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the User Extensions Table is named @code{Configuration_Initial_Extensions} and defined in confdefs.h. It is initialized based on the following macros: @itemize @bullet @item @code{CONFIGURE_INITIAL_EXTENSIONS} @item @code{STACK_CHECKER_EXTENSION} @end itemize The application may configure one or more initial user extension sets by setting the @code{CONFIGURE_INITIAL_EXTENSIONS} macro. By defining the @code{STACK_CHECKER_EXTENSION} macro, the task stack bounds checking user extension set is automatically included in the application. @item User_multiprocessing_table is the address of the Multiprocessor Configuration Table. This table contains information needed by RTEMS only when used in a multiprocessor configuration. This field must be NULL when RTEMS is used in a single processor configuration. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the Multiprocessor Configuration Table is automatically generated when the @code{CONFIGURE_MP_APPLICATION} is defined. If @code{CONFIGURE_MP_APPLICATION} is not defined, the this entry is set to NULL. The generated table has the name @code{Multiprocessing_configuration}. @item RTEMS_api_configuration is the address of the RTEMS API Configuration Table. This table contains information needed by the RTEMS API. This field should be NULL if the RTEMS API is not used. [NOTE: Currently the RTEMS API is required to support support components such as BSPs and libraries which use this API.] This table is built automatically and this entry filled in, if using the @code{rtems/confdefs.h} application configuration mechanism. The generated table has the name @code{Configuration_RTEMS_API}. @item POSIX_api_configuration is the address of the POSIX API Configuration Table. This table contains information needed by the POSIX API. This field should be NULL if the POSIX API is not used. This table is built automatically and this entry filled in, if using the @code{rtems/confdefs.h} application configuration mechanism. The @code{rtems/confdefs.h} application mechanism will fill this field in with the address of the @code{Configuration_POSIX_API} table of POSIX API is configured and NULL if the POSIX API is not configured. @end table @subsection RTEMS API Configuration Table @cindex RTEMS API Configuration Table The RTEMS API Configuration Table is used to configure the managers which constitute the RTEMS API for a particular application. For example, the user can configure the maximum number of tasks for this application. The RTEMS API Configuration Table is defined in the following C structure: @findex rtems_api_configuration_table @example @group typedef struct @{ uint32_t maximum_tasks; uint32_t maximum_timers; uint32_t maximum_semaphores; uint32_t maximum_message_queues; uint32_t maximum_partitions; uint32_t maximum_regions; uint32_t maximum_ports; uint32_t maximum_periods; uint32_t maximum_barriers; uint32_t number_of_initialization_tasks; rtems_initialization_tasks_table *User_initialization_tasks_table; @} rtems_api_configuration_table; @end group @end example @table @b @item maximum_tasks is the maximum number of tasks that can be concurrently active (created) in the system including initialization tasks. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_TASKS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_TASKS} macro defaults to 0. @item maximum_timers is the maximum number of timers that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_TIMERS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_TIMERS} macro defaults to 0. @item maximum_semaphores is the maximum number of semaphores that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_SEMAPHORES}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_SEMAPHORES} macro defaults to 0. @item maximum_message_queues is the maximum number of message queues that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_MESSAGE_QUEUES}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_MESSAGE_QUEUES} macro defaults to 0. @item maximum_partitions is the maximum number of partitions that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_PARTITIONS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_PARTITIONS} macro defaults to 0. @item maximum_regions is the maximum number of regions that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_REGIONS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_REGIONS} macro defaults to 0. @item maximum_ports is the maximum number of ports into dual-port memory areas that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_PORTS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_PORTS} macro defaults to 0. @item number_of_initialization_tasks is the number of initialization tasks configured. At least one RTEMS initialization task or POSIX initializatin must be configured in order for the user's application to begin executing. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the user must define the @code{CONFIGURE_RTEMS_INIT_TASKS_TABLE} to indicate that there is one or more RTEMS initialization task. If the application only has one RTEMS initialization task, then the automatically generated Initialization Task Table will be sufficient. The following macros correspond to the single initialization task: @itemize @bullet @item @code{CONFIGURE_INIT_TASK_NAME} - is the name of the task. If this macro is not defined by the application, then this defaults to the task name of @code{"UI1 "} for User Initialization Task 1. @item @code{CONFIGURE_INIT_TASK_STACK_SIZE} - is the stack size of the single initialization task. If this macro is not defined by the application, then this defaults to configured minimum stack size. @item @code{CONFIGURE_INIT_TASK_PRIORITY} - is the initial priority of the single initialization task. If this macro is not defined by the application, then this defaults to 1. @item @code{CONFIGURE_INIT_TASK_ATTRIBUTES} - is the attributes of the single initialization task. If this macro is not defined by the application, then this defaults to @code{RTEMS_DEFAULT_ATTRIBUTES}. @item @code{CONFIGURE_INIT_TASK_ENTRY_POINT} - is the entry point of the single initialization task. If this macro is not defined by the application, then this defaults to the C language routine @code{Init}. @item @code{CONFIGURE_INIT_TASK_INITIAL_MODES} - is the initial execution modes of the single initialization task. If this macro is not defined by the application, then this defaults to @code{RTEMS_NO_PREEMPT}. @item @code{CONFIGURE_INIT_TASK_ARGUMENTS} - is the argument passed to the of the single initialization task. If this macro is not defined by the application, then this defaults to 0. @end itemize has the option to have value for this field corresponds to the setting of the macro @code{}. @item User_initialization_tasks_table is the address of the Initialization Task Table. This table contains the information needed to create and start each of the initialization tasks. The format of this table will be discussed below. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_EXECUTIVE_RAM_WORK_AREA}. @end table @subsection POSIX API Configuration Table @cindex POSIX API Configuration Table The POSIX API Configuration Table is used to configure the managers which constitute the POSIX API for a particular application. For example, the user can configure the maximum number of threads for this application. The POSIX API Configuration Table is defined in the following C structure: @findex posix_initialization_threads_table @findex posix_api_configuration_table @example @group typedef struct @{ void *(*thread_entry)(void *); @} posix_initialization_threads_table; typedef struct @{ int maximum_threads; int maximum_mutexes; int maximum_condition_variables; int maximum_keys; int maximum_timers; int maximum_queued_signals; int maximum_message_queues; int maximum_message_queue_descriptors; int maximum_semaphores; int maximum_barriers; int maximum_rwlocks; int maximum_spinlocks; int number_of_initialization_threads; posix_initialization_threads_table *User_initialization_tasks_table; @} posix_api_configuration_table; @end group @end example @table @b @item maximum_threads is the maximum number of threads that can be concurrently active (created) in the system including initialization threads. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_THREADS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_THREADS} macro defaults to 0. @item maximum_mutexes is the maximum number of mutexes that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_MUTEXES}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_MUTEXES} macro defaults to 0. @item maximum_condition_variables is the maximum number of condition variables that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_CONDITION_VARIABLES}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_CONDITION_VARIABLES} macro defaults to 0. @item maximum_keys is the maximum number of keys that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_KEYS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_KEYS} macro defaults to 0. @item maximum_timers is the maximum number of POSIX timers that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_TIMERS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_TIMERS} macro defaults to 0. @item maximum_queued_signals is the maximum number of queued signals that can be concurrently pending in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_QUEUED_SIGNALS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_QUEUED_SIGNALS} macro defaults to 0. @item maximum_message_queues is the maximum number of POSIX message queues that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES} macro defaults to 0. @item maximum_message_queue_descriptors is the maximum number of POSIX message queue descriptors that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUE_DESCRIPTORS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUE_DESCRIPTORS} macro defaults to the value of @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES} @item maximum_semaphores is the maximum number of POSIX semaphore that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_SEMAPHORES}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_SEMAPHORES} macro defaults to 0. @item maximum_barriers is the maximum number of POSIX barriers that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_BARRIERS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_BARRIERS} macro defaults to 0. @item maximum_rwlocks is the maximum number of POSIX rwlocks that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_SPINLOCKS}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_SPINLOCKS} macro defaults to 0. @item maximum_spinlocks is the maximum number of POSIX spinlocks that can be concurrently active in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES}. If not defined by the application, then the @code{CONFIGURE_MAXIMUM_POSIX_MESSAGE_QUEUES} macro defaults to 0. @item number_of_initialization_threads is the number of initialization threads configured. At least one initialization threads must be configured. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the user must define the @code{CONFIGURE_POSIX_INIT_THREAD_TABLE} to indicate that there is one or more POSIX initialization thread. If the application only has one POSIX initialization thread, then the automatically generated POSIX Initialization Thread Table will be sufficient. The following macros correspond to the single initialization task: @itemize @bullet @item @code{CONFIGURE_POSIX_INIT_THREAD_ENTRY_POINT} - is the entry point of the thread. If this macro is not defined by the application, then this defaults to the C routine @code{POSIX_Init}. @item @code{CONFIGURE_POSIX_INIT_TASK_STACK_SIZE} - is the stack size of the single initialization thread. If this macro is not defined by the application, then this defaults to twice the configured minimum stack size. @end itemize @item User_initialization_threads_table is the address of the Initialization Threads Table. This table contains the information needed to create and start each of the initialization threads. The format of each entry in this table is defined in the @code{posix_initialization_threads_table} structure. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the address of the @code{POSIX_Initialization_threads} structure. @end table @subsection CPU Dependent Information Table @cindex CPU Dependent Information Table The CPU Dependent Information Table is used to describe processor dependent information required by RTEMS. This table is generally used to supply RTEMS with information only known by the Board Support Package. The contents of this table are discussed in the CPU Dependent Information Table chapter of the Applications Supplement document for a specific target processor. The @code{rtems/confdefs.h} mechanism does not support generating this table. It is normally filled in by the Board Support Package. @subsection Initialization Task Table @cindex Initialization Tasks Table The Initialization Task Table is used to describe each of the user initialization tasks to the Initialization Manager. The table contains one entry for each initialization task the user wishes to create and start. The fields of this data structure directly correspond to arguments to the @code{@value{DIRPREFIX}task_create} and @code{@value{DIRPREFIX}task_start} directives. The number of entries is found in the @code{number_of_initialization_tasks} entry in the Configuration Table. The format of each entry in the Initialization Task Table is defined in the following C structure: @findex rtems_initialization_tasks_table @example typedef struct @{ rtems_name name; size_t stack_size; rtems_task_priority initial_priority; rtems_attribute attribute_set; rtems_task_entry entry_point; rtems_mode mode_set; rtems_task_argument argument; @} rtems_initialization_tasks_table; @end example @table @b @item name is the name of this initialization task. @item stack_size is the size of the stack for this initialization task. @item initial_priority is the priority of this initialization task. @item attribute_set is the attribute set used during creation of this initialization task. @item entry_point is the address of the entry point of this initialization task. @item mode_set is the initial execution mode of this initialization task. @item argument is the initial argument for this initialization task. @end table A typical declaration for an Initialization Task Table might appear as follows: @example rtems_initialization_tasks_table Initialization_tasks[2] = @{ @{ INIT_1_NAME, 1024, 1, DEFAULT_ATTRIBUTES, Init_1, DEFAULT_MODES, 1 @}, @{ INIT_2_NAME, 1024, 250, FLOATING_POINT, Init_2, NO_PREEMPT, 2 @} @}; @end example @subsection Driver Address Table @cindex Device Driver Table The Device Driver Table is used to inform the I/O Manager of the set of entry points for each device driver configured in the system. The table contains one entry for each device driver required by the application. The number of entries is defined in the number_of_device_drivers entry in the Configuration Table. This table is copied to the Device Drive Table during the IO Manager's initialization giving the entries in this table the lower major numbers. The format of each entry in the Device Driver Table is defined in the following C structure: @findex rtems_driver_address_table @example typedef struct @{ rtems_device_driver_entry initialization_entry; rtems_device_driver_entry open_entry; rtems_device_driver_entry close_entry; rtems_device_driver_entry read_entry; rtems_device_driver_entry write_entry; rtems_device_driver_entry control_entry; @} rtems_driver_address_table; @end example @table @b @item initialization_entry is the address of the entry point called by @code{rtems_io_initialize} to initialize a device driver and its associated devices. @item open_entry is the address of the entry point called by @code{rtems_io_open}. @item close_entry is the address of the entry point called by @code{rtems_io_close}. @item read_entry is the address of the entry point called by @code{rtems_io_read}. @item write_entry is the address of the entry point called by @code{rtems_io_write}. @item control_entry is the address of the entry point called by @code{rtems_io_control}. @end table Driver entry points configured as NULL will always return a status code of @code{@value{RPREFIX}SUCCESSFUL}. No user code will be executed in this situation. A typical declaration for a Device Driver Table might appear as follows: @example rtems_driver_address_table Driver_table[2] = @{ @{ tty_initialize, tty_open, tty_close, /* major = 0 */ tty_read, tty_write, tty_control @}, @{ lp_initialize, lp_open, lp_close, /* major = 1 */ NULL, lp_write, lp_control @} @}; @end example More information regarding the construction and operation of device drivers is provided in the I/O Manager chapter. @subsection User Extensions Table @cindex User Extensions Table The User Extensions Table is used to inform RTEMS of the optional user-supplied static extension set. This table contains one entry for each possible extension. The entries are called at critical times in the life of the system and individual tasks. The application may create dynamic extensions in addition to this single static set. The format of each entry in the User Extensions Table is defined in the following C structure: @example typedef void rtems_extension; typedef void (*rtems_task_create_extension)( Thread_Control * /* executing */, Thread_Control * /* created */ ); typedef void (*rtems_task_delete_extension)( Thread_Control * /* executing */, Thread_Control * /* deleted */ ); typedef void (*rtems_task_start_extension)( Thread_Control * /* executing */, Thread_Control * /* started */ ); typedef void (*rtems_task_restart_extension)( Thread_Control * /* executing */, Thread_Control * /* restarted */ ); typedef void (*rtems_task_switch_extension)( Thread_Control * /* executing */, Thread_Control * /* heir */ ); typedef void (*rtems_task_begin_extension)( Thread_Control * /* beginning */ ); typedef void (*rtems_task_exitted_extension)( Thread_Control * /* exiting */ ); typedef void (*rtems_fatal_extension)( Internal_errors_Source /* the_source */, bool /* is_internal */, uint32_t /* the_error */ ); typedef struct @{ rtems_task_create_extension thread_create; rtems_task_start_extension thread_start; rtems_task_restart_extension thread_restart; rtems_task_delete_extension thread_delete; rtems_task_switch_extension thread_switch; rtems_task_begin_extension thread_begin; rtems_task_exitted_extension thread_exitted; rtems_fatal_extension fatal; @} rtems_extensions_table; @end example @table @b @item thread_create is the address of the user-supplied subroutine for the TASK_CREATE extension. If this extension for task creation is defined, it is called from the task_create directive. A value of NULL indicates that no extension is provided. @item thread_start is the address of the user-supplied subroutine for the TASK_START extension. If this extension for task initiation is defined, it is called from the task_start directive. A value of NULL indicates that no extension is provided. @item thread_restart is the address of the user-supplied subroutine for the TASK_RESTART extension. If this extension for task re-initiation is defined, it is called from the task_restart directive. A value of NULL indicates that no extension is provided. @item thread_delete is the address of the user-supplied subroutine for the TASK_DELETE extension. If this RTEMS extension for task deletion is defined, it is called from the task_delete directive. A value of NULL indicates that no extension is provided. @item thread_switch is the address of the user-supplied subroutine for the task context switch extension. This subroutine is called from RTEMS dispatcher after the current task has been swapped out but before the new task has been swapped in. A value of NULL indicates that no extension is provided. As this routine is invoked after saving the current task's context and before restoring the heir task's context, it is not necessary for this routine to save and restore any registers. @item thread_begin is the address of the user-supplied subroutine which is invoked immediately before a task begins execution. It is invoked in the context of the beginning task. A value of NULL indicates that no extension is provided. @item thread_exitted is the address of the user-supplied subroutine which is invoked when a task exits. This procedure is responsible for some action which will allow the system to continue execution (i.e. delete or restart the task) or to terminate with a fatal error. If this field is set to NULL, the default RTEMS TASK_EXITTED handler will be invoked. @item fatal is the address of the user-supplied subroutine for the FATAL extension. This RTEMS extension of fatal error handling is called from the @code{@value{DIRPREFIX}fatal_error_occurred} directive. If the user's fatal error handler returns or if this entry is NULL then the default RTEMS fatal error handler will be executed. @end table A typical declaration for a User Extension Table which defines the TASK_CREATE, TASK_DELETE, TASK_SWITCH, and FATAL extension might appear as follows: @example rtems_extensions_table User_extensions = @{ task_create_extension, NULL, NULL, task_delete_extension, task_switch_extension, NULL, NULL, fatal_extension @}; @end example More information regarding the user extensions is provided in the User Extensions chapter. @subsection Multiprocessor Configuration Table @cindex Multiprocessor Configuration Table The Multiprocessor Configuration Table contains information needed when using RTEMS in a multiprocessor configuration. Many of the details associated with configuring a multiprocessor system are dependent on the multiprocessor communications layer provided by the user. The address of the Multiprocessor Configuration Table should be placed in the @code{User_multiprocessing_table} entry in the primary Configuration Table. Further details regarding many of the entries in the Multiprocessor Configuration Table will be provided in the Multiprocessing chapter. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the macro @code{CONFIGURE_MP_APPLICATION} must be defined to automatically generate the Multiprocessor Configuration Table. If @code{CONFIGURE_MP_APPLICATION}, is not defined, then a NULL pointer is configured as the address of this table. The format of the Multiprocessor Configuration Table is defined in the following C structure: @example typedef struct @{ uint32_t node; uint32_t maximum_nodes; uint32_t maximum_global_objects; uint32_t maximum_proxies; uint32_t extra_mpci_receive_server_stack; rtems_mpci_table *User_mpci_table; @} rtems_multiprocessing_table; @end example @table @b @item node is a unique processor identifier and is used in routing messages between nodes in a multiprocessor configuration. Each processor must have a unique node number. RTEMS assumes that node numbers start at one and increase sequentially. This assumption can be used to advantage by the user-supplied MPCI layer. Typically, this requirement is made when the node numbers are used to calculate the address of inter-processor communication links. Zero should be avoided as a node number because some MPCI layers use node zero to represent broadcasted packets. Thus, it is recommended that node numbers start at one and increase sequentially. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MP_NODE_NUMBER}. If not defined by the application, then the @code{CONFIGURE_MP_NODE_NUMBER} macro defaults to the value of the @code{NODE_NUMBER} macro which is set on the compiler command line by the RTEMS Multiprocessing Test Suites. @item maximum_nodes is the number of processor nodes in the system. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MP_MAXIMUM_NODES}. If not defined by the application, then the @code{CONFIGURE_MP_MAXIMUM_NODES} macro defaults to the value 2. @item maximum_global_objects is the maximum number of global objects which can exist at any given moment in the entire system. If this parameter is not the same on all nodes in the system, then a fatal error is generated to inform the user that the system is inconsistent. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MP_MAXIMUM_GLOBAL_OBJECTS}. If not defined by the application, then the @code{CONFIGURE_MP_MAXIMUM_GLOBAL_OBJECTS} macro defaults to the value 32. @item maximum_proxies is the maximum number of proxies which can exist at any given moment on this particular node. A proxy is a substitute task control block which represent a task residing on a remote node when that task blocks on a remote object. Proxies are used in situations in which delayed interaction is required with a remote node. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MP_MAXIMUM_PROXIES}. If not defined by the application, then the @code{CONFIGURE_MP_MAXIMUM_PROXIES} macro defaults to the value 32. @item extra_mpci_receive_server_stack is the extra stack space allocated for the RTEMS MPCI receive server task in bytes. The MPCI receive server may invoke nearly all directives and may require extra stack space on some targets. @item User_mpci_table is the address of the Multiprocessor Communications Interface Table. This table contains the entry points of user-provided functions which constitute the multiprocessor communications layer. This table must be provided in multiprocessor configurations with all entries configured. The format of this table and details regarding its entries can be found in the next section. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the value for this field corresponds to the setting of the macro @code{CONFIGURE_MP_MPCI_TABLE_POINTER}. If not defined by the application, then the @code{CONFIGURE_MP_MPCI_TABLE_POINTER} macro defaults to the address of the table named @code{MPCI_table}. @end table @subsection Multiprocessor Communications Interface Table @cindex Multiprocessor Communications Interface Table This table defines the set of callouts that must be provided by an Multiprocessor Communications Interface implementation. When using the @code{rtems/confdefs.h} mechanism for configuring an RTEMS application, the name of this table is assumed to be @code{MPCI_table} unless the application sets the @code{CONFIGURE_MP_MPCI_TABLE_POINTER} when configuring a multiprocessing system. The format of this table is defined in the following C structure: @example typedef struct @{ uint32_t default_timeout; /* in ticks */ uint32_t maximum_packet_size; rtems_mpci_initialization_entry initialization; rtems_mpci_get_packet_entry get_packet; rtems_mpci_return_packet_entry return_packet; rtems_mpci_send_entry send_packet; rtems_mpci_receive_entry receive_packet; @} rtems_mpci_table; @end example @table @b @item default_timeout is the default maximum length of time a task should block waiting for a response to a directive which results in communication with a remote node. The maximum length of time is a function the user supplied multiprocessor communications layer and the media used. This timeout only applies to directives which would not block if the operation were performed locally. @item maximum_packet_size is the size in bytes of the longest packet which the MPCI layer is capable of sending. This value should represent the total number of bytes available for a RTEMS interprocessor messages. @item initialization is the address of the entry point for the initialization procedure of the user supplied multiprocessor communications layer. @item get_packet is the address of the entry point for the procedure called by RTEMS to obtain a packet from the user supplied multiprocessor communications layer. @item return_packet is the address of the entry point for the procedure called by RTEMS to return a packet to the user supplied multiprocessor communications layer. @item send is the address of the entry point for the procedure called by RTEMS to send an envelope to another node. This procedure is part of the user supplied multiprocessor communications layer. @item receive is the address of the entry point for the procedure called by RTEMS to retrieve an envelope containing a message from another node. This procedure is part of the user supplied multiprocessor communications layer. @end table More information regarding the required functionality of these entry points is provided in the Multiprocessor chapter. @subsection Determining Memory Requirements Since memory is a critical resource in many real-time embedded systems, the RTEMS Classic API was specifically designed to allow unused managers to be forcibly excluded from the run-time environment. This allows the application designer the flexibility to tailor RTEMS to most efficiently meet system requirements while still satisfying even the most stringent memory constraints. As result, the size of the RTEMS executive is application dependent. It is not necessary for RTEMS Application Developers to calculate the amount of memory required for the RTEMS Workspace. This is done automatically by @code{}. See @ref{Configuring a System Sizing the RTEMS RAM Workspace} for more details on how this works. In the event, you are interested in the memory required for an instance of a particular RTEMS object, please run the test @code{spsize} on your target board. RTEMS is built to be a library and any routines that you do not directly or indirectly require in your application will @b{NOT} be included in your executable image. However, some managers may be explicitly excluded and no attempt to create these instances of these objects will succeed even if they are configured. The following Classic API managers may be optionally excluded: @itemize @bullet @item signal @item region @item dual ported memory @item event @item multiprocessing @item partition @item timer @item semaphore @item message @item rate monotonic @end itemize RTEMS is designed to be built and installed as a library that is linked into the application. As such, much of RTEMS is implemented in such a way that there is a single entry point per source file. This avoids having the linker being forced to pull large object files in their entirety into an application when the application references a single symbol. In the event you discover an RTEMS method that is included in your executable but never entered, please let us know. It might be an opportunity to break a dependency and shrink many RTEMS applications. RTEMS based applications must somehow provide memory for RTEMS' code and data space. Although RTEMS' data space must be in RAM, its code space can be located in either ROM or RAM. In addition, the user must allocate RAM for the RTEMS RAM Workspace. The size of this area is application dependent and can be calculated using the formula provided in the Memory Requirements chapter of the Applications Supplement document for a specific target processor. All private RTEMS data variables and routine names used by RTEMS begin with the underscore ( _ ) character followed by an upper-case letter. If RTEMS is linked with an application, then the application code should NOT contain any symbols which begin with the underscore character and followed by an upper-case letter to avoid any naming conflicts. All RTEMS directive names should be treated as reserved words. @subsection Sizing the RTEMS RAM Workspace The RTEMS RAM Workspace is a user-specified block of memory reserved for use by RTEMS. The application should NOT modify this memory. This area consists primarily of the RTEMS data structures whose exact size depends upon the values specified in the Configuration Table. In addition, task stacks and floating point context areas are dynamically allocated from the RTEMS RAM Workspace. The @code{rtems/confdefs.h} mechanism calcalutes the size of the RTEMS RAM Workspace automatically. It assumes that all tasks are floating point and that all will be allocated the miminum stack space. This calculation also automatically includes the memory that will be allocated for internal use by RTEMS. The following macros may be set by the application to make the calculation of memory required more accurate: @itemize @bullet @item @code{CONFIGURE_MEMORY_OVERHEAD} @item @code{CONFIGURE_EXTRA_TASK_STACKS} @end itemize The starting address of the RTEMS RAM Workspace must be aligned on a four-byte boundary. Failure to properly align the workspace area will result in the @code{@value{DIRPREFIX}fatal_error_occurred} directive being invoked with the @code{@value{RPREFIX}INVALID_ADDRESS} error code. The file @code{} will calculate the value that is specified as the @code{work_space_size} parameter of the Configuration Table. There are many parameters the application developer can specify to help @code{} in its calculations. Correctly specifying the application requirements via parameters such as @code{CONFIGURE_EXTRA_TASK_STACKS} and @code{CONFIGURE_MAXIMUM_TASKS} is critical. The allocation of objects can operate in two modes. The default mode has an object number ceiling. No more than the specified number of objects can be allocated from the RTEMS RAM Workspace. The number of objects specified in the particular API Configuration table fields are allocated at initialisation. The second mode allows the number of objects to grow to use the available free memory in the RTEMS RAM Workspace. The auto-extending mode can be enabled individually for each object type by using the macro @code{rtems_resource_unlimited}. This takes a value as a parameter, and is used to set the object maximum number field in an API Configuration table. The value is an allocation unit size. When RTEMS is required to grow the object table it is grown by this size. The kernel will return the object memory back to the RTEMS RAM Workspace when an object is destroyed. The kernel will only return an allocated block of objects to the RTEMS RAM Workspace if at least half the allocation size of free objects remain allocated. RTEMS always keeps one allocation block of objects allocated. Here is an example of using @code{rtems_resource_unlimited}: @example #define CONFIGURE_MAXIMUM_TASKS rtems_resource_unlimited(5) @end example The user is cautioned that future versions of RTEMS may not have the same memory requirements per object. Although the value calculated is suficient for a particular target processor and release of RTEMS, memory usage is subject to change across versions and target processors. To avoid problems, the user should accurately specify each configuration parameter and allow @code{} to calculate the memory requirements. The memory requirements are likely to change each time one of the following events occurs: @itemize @bullet @item a configuration parameter is modified, @item task or interrupt stack requirements change, @item task floating point attribute is altered, @item RTEMS is upgraded, or @item the target processor is changed. @end itemize Failure to provide enough space in the RTEMS RAM Workspace will result in the @code{@value{DIRPREFIX}fatal_error_occurred} directive being invoked with the appropriate error code.