.. SPDX-License-Identifier: CC-BY-SA-4.0 .. Copyright (C) 2008, 2021 embedded brains GmbH & Co. KG .. Copyright (C) 1988, 2017 On-Line Applications Research Corporation (OAR) .. This file is part of the RTEMS quality process and was automatically .. generated. If you find something that needs to be fixed or .. worded better please post a report or patch to an RTEMS mailing list .. or raise a bug report: .. .. https://www.rtems.org/bugs.html .. .. For information on updating and regenerating please refer to the How-To .. section in the Software Requirements Engineering chapter of the .. RTEMS Software Engineering manual. The manual is provided as a part of .. a release. For development sources please refer to the online .. documentation at: .. .. https://docs.rtems.org .. index:: RTEMS Data Types .. index:: data types RTEMS Data Types **************** .. _Introduction: Introduction ============ This chapter contains a complete list of the RTEMS primitive data types in alphabetical order. This is intended to be an overview and the user is encouraged to look at the appropriate chapters in the manual for more information about the usage of the various data types. .. _ListOfDataTypes: List of Data Types ================== The following is a complete list of the RTEMS primitive data types in alphabetical order: .. Generated from spec:/rtems/io/if/bsp-output-char-function-type .. index:: BSP_output_char_function_type .. _InterfaceBSPOutputCharFunctionType: BSP_output_char_function_type ----------------------------- Polled character output functions shall have this type. .. Generated from spec:/rtems/io/if/bsp-polling-getchar-function-type .. index:: BSP_polling_getchar_function_type .. _InterfaceBSPPollingGetcharFunctionType: BSP_polling_getchar_function_type --------------------------------- Polled character input functions shall have this type. .. Generated from spec:/rtems/timer/if/classes .. index:: Timer_Classes .. _InterfaceTimerClasses: Timer_Classes ------------- The timer class indicates how the timer was most recently fired. .. rubric:: ENUMERATORS: TIMER_DORMANT This timer class indicates that the timer was never in use. TIMER_INTERVAL This timer class indicates that the timer is currently in use as an interval timer which will fire in the context of the clock tick :term:`ISR`. TIMER_INTERVAL_ON_TASK This timer class indicates that the timer is currently in use as an interval timer which will fire in the context of the Timer Server task. TIMER_TIME_OF_DAY This timer class indicates that the timer is currently in use as an time of day timer which will fire in the context of the clock tick :term:`ISR`. TIMER_TIME_OF_DAY_ON_TASK This timer class indicates that the timer is currently in use as an time of day timer which will fire in the context of the Timer Server task. .. Generated from spec:/rtems/config/if/api-table .. index:: rtems_api_configuration_table .. _InterfaceRtemsApiConfigurationTable: rtems_api_configuration_table ----------------------------- This structure contains a summary of the Classic API configuration. .. rubric:: MEMBERS: maximum_tasks This member contains the maximum number of Classic API Tasks configured for this application. See :ref:`CONFIGURE_MAXIMUM_TASKS`. notepads_enabled This member is true, if the Classic API Notepads are enabled, otherwise it is false. maximum_timers This member contains the maximum number of Classic API Timers configured for this application. See :ref:`CONFIGURE_MAXIMUM_TIMERS`. maximum_semaphores This member contains the maximum number of Classic API Semaphores configured for this application. See :ref:`CONFIGURE_MAXIMUM_SEMAPHORES`. maximum_message_queues This member contains the maximum number of Classic API Message Queues configured for this application. See :ref:`CONFIGURE_MAXIMUM_MESSAGE_QUEUES`. maximum_partitions This member contains the maximum number of Classic API Partitions configured for this application. See :ref:`CONFIGURE_MAXIMUM_PARTITIONS`. maximum_regions This member contains the maximum number of Classic API Regions configured for this application. See :ref:`CONFIGURE_MAXIMUM_REGIONS`. maximum_ports This member contains the maximum number of Classic API Dual-Ported Memories configured for this application. See :ref:`CONFIGURE_MAXIMUM_PORTS`. maximum_periods This member contains the maximum number of Classic API Rate Monotonic Periods configured for this application. See :ref:`CONFIGURE_MAXIMUM_PERIODS`. maximum_barriers This member contains the maximum number of Classic API Barriers configured for this application. See :ref:`CONFIGURE_MAXIMUM_BARRIERS`. number_of_initialization_tasks This member contains the number of Classic API Initialization Tasks configured for this application. See :ref:`CONFIGURE_RTEMS_INIT_TASKS_TABLE`. User_initialization_tasks_table This member contains the pointer to Classic API Initialization Tasks Table of this application. See :ref:`CONFIGURE_RTEMS_INIT_TASKS_TABLE`. .. rubric:: DESCRIPTION: Use :ref:`InterfaceRtemsConfigurationGetRtemsApiConfiguration` to get the configuration table. .. Generated from spec:/rtems/signal/if/asr .. index:: rtems_asr .. _InterfaceRtemsAsr: rtems_asr --------- This type defines the return type of routines which are used to process asynchronous signals. .. rubric:: NOTES: This type can be used to document asynchronous signal routines in the source code. .. Generated from spec:/rtems/signal/if/asr-entry .. index:: rtems_asr_entry .. _InterfaceRtemsAsrEntry: rtems_asr_entry --------------- This type defines the prototype of routines which are used to process asynchronous signals. .. Generated from spec:/rtems/fatal/if/assert-context .. index:: rtems_assert_context .. _InterfaceRtemsAssertContext: rtems_assert_context -------------------- This structure provides the context in which an assertion failed. .. rubric:: MEMBERS: file This member provides the file name of the source code file containing the failed assertion statement. line This member provides the line number in the source code file containing the failed assertion statement. function This member provides the function name containing the failed assertion statement. failed_expression This member provides the expression of the failed assertion statement. .. Generated from spec:/rtems/attr/if/attribute .. index:: rtems_attribute .. _InterfaceRtemsAttribute: rtems_attribute --------------- This type represents Classic API attributes. .. rubric:: NOTES: Attributes are primarily used when creating objects. .. Generated from spec:/rtems/io/if/device-driver .. index:: rtems_device_driver .. _InterfaceRtemsDeviceDriver: rtems_device_driver ------------------- This type shall be used in device driver entry declarations and definitions. .. rubric:: NOTES: Device driver entries return an :c:type:`rtems_status_code` status code. This type definition helps to document device driver entries in the source code. .. Generated from spec:/rtems/io/if/device-driver-entry .. index:: rtems_device_driver_entry .. _InterfaceRtemsDeviceDriverEntry: rtems_device_driver_entry ------------------------- Device driver entries shall have this type. .. Generated from spec:/rtems/io/if/device-major-number .. index:: rtems_device_major_number .. _InterfaceRtemsDeviceMajorNumber: rtems_device_major_number ------------------------- This integer type represents the major number of devices. .. rubric:: NOTES: The major number of a device is determined by :ref:`InterfaceRtemsIoRegisterDriver` and the application configuration (see :ref:`CONFIGURE_MAXIMUM_DRIVERS`) . .. Generated from spec:/rtems/io/if/device-minor-number .. index:: rtems_device_minor_number .. _InterfaceRtemsDeviceMinorNumber: rtems_device_minor_number ------------------------- This integer type represents the minor number of devices. .. rubric:: NOTES: The minor number of devices is managed by the device driver. .. Generated from spec:/rtems/io/if/driver-address-table .. index:: rtems_driver_address_table .. _InterfaceRtemsDriverAddressTable: rtems_driver_address_table -------------------------- This structure contains the device driver entries. .. rubric:: MEMBERS: initialization_entry This member is the device driver initialization entry. This entry is called by :ref:`InterfaceRtemsIoInitialize`. open_entry This member is the device driver open entry. This entry is called by :ref:`InterfaceRtemsIoOpen`. close_entry This member is the device driver close entry. This entry is called by :ref:`InterfaceRtemsIoClose`. read_entry This member is the device driver read entry. This entry is called by :ref:`InterfaceRtemsIoRead`. write_entry This member is the device driver write entry. This entry is called by :ref:`InterfaceRtemsIoWrite`. control_entry This member is the device driver control entry. This entry is called by :ref:`InterfaceRtemsIoControl`. .. rubric:: DESCRIPTION: This structure is used to register a device driver via :ref:`InterfaceRtemsIoRegisterDriver`. .. Generated from spec:/rtems/event/if/set .. index:: rtems_event_set .. _InterfaceRtemsEventSet: rtems_event_set --------------- This integer type represents a bit field which can hold exactly 32 individual events. .. Generated from spec:/rtems/fatal/if/exception-frame .. index:: rtems_exception_frame .. _InterfaceRtemsExceptionFrame: rtems_exception_frame --------------------- This structure represents an architecture-dependent exception frame. .. Generated from spec:/rtems/userext/if/table .. index:: rtems_extensions_table .. _InterfaceRtemsExtensionsTable: rtems_extensions_table ---------------------- The extensions table contains a set of extensions which may be registered in the system through the :ref:`CONFIGURE_INITIAL_EXTENSIONS` application configuration option or the :ref:`InterfaceRtemsExtensionCreate` directive. .. Generated from spec:/rtems/userext/if/fatal-code .. index:: rtems_fatal_code .. _InterfaceRtemsFatalCode: rtems_fatal_code ---------------- This integer type represents system termination codes. .. rubric:: DESCRIPTION: This integer type is large enough to store a 32-bit integer or a pointer. .. rubric:: NOTES: The interpretation of a system termination code depends on the system termination source, see :ref:`InterfaceRtemsFatalSource`. .. Generated from spec:/rtems/userext/if/fatal .. index:: rtems_fatal_extension .. _InterfaceRtemsFatalExtension: rtems_fatal_extension --------------------- Fatal extensions are invoked when the system should terminate. .. rubric:: NOTES: The fatal extensions are invoked in :term:`extension forward order`. The fatal extension should be extremely careful with respect to the RTEMS directives it calls. Depending on the system termination source, the system may be in an undefined and corrupt state. It is recommended to register fatal extensions through :term:`initial extension sets`, see :ref:`CONFIGURE_INITIAL_EXTENSIONS`. .. Generated from spec:/rtems/userext/if/fatal-source .. index:: rtems_fatal_source .. _InterfaceRtemsFatalSource: rtems_fatal_source ------------------ This enumeration represents system termination sources. .. rubric:: NOTES: The system termination code may provide additional information depending on the system termination source, see :ref:`InterfaceRtemsFatalCode`. .. Generated from spec:/rtems/type/if/id .. index:: rtems_id .. _InterfaceRtemsId: rtems_id -------- This type represents RTEMS object identifiers. .. Generated from spec:/rtems/task/if/initialization-table .. index:: rtems_initialization_tasks_table .. _InterfaceRtemsInitializationTasksTable: rtems_initialization_tasks_table -------------------------------- This structure defines the properties of the Classic API user initialization task. .. rubric:: MEMBERS: name This member defines the task name. stack_size This member defines the task stack size in bytes. initial_priority This member defines the initial task priority. attribute_set This member defines the attribute set of the task. entry_point This member defines the entry point of the task. mode_set This member defines the initial modes of the task. argument This member defines the entry point argument of the task. .. Generated from spec:/rtems/intr/if/attributes .. index:: rtems_interrupt_attributes .. _InterfaceRtemsInterruptAttributes: rtems_interrupt_attributes -------------------------- This structure provides the attributes of an interrupt vector. .. rubric:: MEMBERS: is_maskable This member is true, if the interrupt vector is maskable by :ref:`InterfaceRtemsInterruptLocalDisable`, otherwise it is false. Interrupt vectors which are not maskable by :ref:`InterfaceRtemsInterruptLocalDisable` should be used with care since they cannot use most operating system services. can_enable This member is true, if the interrupt vector can be enabled by :ref:`InterfaceRtemsInterruptVectorEnable`, otherwise it is false. When an interrupt vector can be enabled, this means that the enabled state can always be changed from disabled to enabled. For an interrupt vector which can be enabled it follows that it may be enabled. maybe_enable This member is true, if the interrupt vector may be enabled by :ref:`InterfaceRtemsInterruptVectorEnable`, otherwise it is false. When an interrupt vector may be enabled, this means that the enabled state may be changed from disabled to enabled. The requested enabled state change should be checked by :ref:`InterfaceRtemsInterruptVectorIsEnabled`. Some interrupt vectors may be optionally available and cannot be enabled on a particular :term:`target`. can_disable This member is true, if the interrupt vector can be disabled by :ref:`InterfaceRtemsInterruptVectorDisable`, otherwise it is false. When an interrupt vector can be disabled, this means that the enabled state can be changed from enabled to disabled. For an interrupt vector which can be disabled it follows that it may be disabled. maybe_disable This member is true, if the interrupt vector may be disabled by :ref:`InterfaceRtemsInterruptVectorDisable`, otherwise it is false. When an interrupt vector may be disabled, this means that the enabled state may be changed from enabled to disabled. The requested enabled state change should be checked by :ref:`InterfaceRtemsInterruptVectorIsEnabled`. Some interrupt vectors may be always enabled and cannot be disabled on a particular :term:`target`. can_raise This member is true, if the interrupt vector can be raised by :ref:`InterfaceRtemsInterruptRaise`, otherwise it is false. can_raise_on This member is true, if the interrupt vector can be raised on a processor by :ref:`InterfaceRtemsInterruptRaiseOn`, otherwise it is false. can_clear This member is true, if the interrupt vector can be cleared by :ref:`InterfaceRtemsInterruptClear`, otherwise it is false. cleared_by_acknowledge This member is true, if the pending status of the interrupt associated with the interrupt vector is cleared by an interrupt acknowledge from the processor, otherwise it is false. can_get_affinity This member is true, if the affinity set of the interrupt vector can be obtained by :ref:`InterfaceRtemsInterruptGetAffinity`, otherwise it is false. can_set_affinity This member is true, if the affinity set of the interrupt vector can be set by :ref:`InterfaceRtemsInterruptSetAffinity`, otherwise it is false. can_be_triggered_by_message This member is true, if the interrupt associated with the interrupt vector can be triggered by a message. Interrupts may be also triggered by signals, :ref:`InterfaceRtemsInterruptRaise`, or :ref:`InterfaceRtemsInterruptRaiseOn`. Examples for message triggered interrupts are the PCIe MSI/MSI-X and the ARM GICv3 Locality-specific Peripheral Interrupts (LPI). trigger_signal This member describes the trigger signal of the interrupt associated with the interrupt vector. Interrupts are normally triggered by signals which indicate an interrupt request from a peripheral. Interrupts may be also triggered by messages, :ref:`InterfaceRtemsInterruptRaise`, or :ref:`InterfaceRtemsInterruptRaiseOn`. .. rubric:: DESCRIPTION: The :ref:`InterfaceRtemsInterruptGetAttributes` directive may be used to obtain the attributes of an interrupt vector. .. Generated from spec:/rtems/intr/if/entry .. index:: rtems_interrupt_entry .. _InterfaceRtemsInterruptEntry: rtems_interrupt_entry --------------------- This structure represents an interrupt entry. .. rubric:: MEMBERS: Members of the type shall not be accessed directly by the application. .. rubric:: NOTES: This structure shall be treated as an opaque data type from the :term:`API` point of view. Members shall not be accessed directly. An entry may be initialized by :ref:`InterfaceRTEMSINTERRUPTENTRYINITIALIZER` or :ref:`InterfaceRtemsInterruptEntryInitialize`. It may be installed for an interrupt vector with :ref:`InterfaceRtemsInterruptEntryInstall` and removed from an interrupt vector by :ref:`InterfaceRtemsInterruptEntryRemove`. .. Generated from spec:/rtems/intr/if/handler .. index:: rtems_interrupt_handler .. _InterfaceRtemsInterruptHandler: rtems_interrupt_handler ----------------------- Interrupt handler routines shall have this type. .. Generated from spec:/rtems/intr/if/level .. index:: rtems_interrupt_level .. _InterfaceRtemsInterruptLevel: rtems_interrupt_level --------------------- This integer type represents interrupt levels. .. Generated from spec:/rtems/intr/if/lock .. index:: rtems_interrupt_lock .. _InterfaceRtemsInterruptLock: rtems_interrupt_lock -------------------- This structure represents an ISR lock. .. Generated from spec:/rtems/intr/if/lock-context .. index:: rtems_interrupt_lock_context .. _InterfaceRtemsInterruptLockContext: rtems_interrupt_lock_context ---------------------------- This structure provides an ISR lock context for acquire and release pairs. .. Generated from spec:/rtems/intr/if/per-handler-routine .. index:: rtems_interrupt_per_handler_routine .. _InterfaceRtemsInterruptPerHandlerRoutine: rtems_interrupt_per_handler_routine ----------------------------------- Visitor routines invoked by :ref:`InterfaceRtemsInterruptHandlerIterate` shall have this type. .. Generated from spec:/rtems/intr/if/server-action .. index:: rtems_interrupt_server_action .. _InterfaceRtemsInterruptServerAction: rtems_interrupt_server_action ----------------------------- This structure represents an interrupt server action. .. rubric:: MEMBERS: Members of the type shall not be accessed directly by the application. .. rubric:: NOTES: This structure shall be treated as an opaque data type from the :term:`API` point of view. Members shall not be accessed directly. .. Generated from spec:/rtems/intr/if/server-config .. index:: rtems_interrupt_server_config .. _InterfaceRtemsInterruptServerConfig: rtems_interrupt_server_config ----------------------------- This structure defines an interrupt server configuration. .. rubric:: MEMBERS: Members of the type shall not be accessed directly by the application. .. rubric:: NOTES: See also :ref:`InterfaceRtemsInterruptServerCreate`. .. Generated from spec:/rtems/intr/if/server-control .. index:: rtems_interrupt_server_control .. _InterfaceRtemsInterruptServerControl: rtems_interrupt_server_control ------------------------------ This structure represents an interrupt server. .. rubric:: MEMBERS: Members of the type shall not be accessed directly by the application. .. rubric:: NOTES: This structure shall be treated as an opaque data type from the :term:`API` point of view. Members shall not be accessed directly. The structure is initialized by :ref:`InterfaceRtemsInterruptServerCreate` and maintained by the interrupt server support. .. Generated from spec:/rtems/intr/if/server-entry .. index:: rtems_interrupt_server_entry .. _InterfaceRtemsInterruptServerEntry: rtems_interrupt_server_entry ---------------------------- This structure represents an interrupt server entry. .. rubric:: MEMBERS: Members of the type shall not be accessed directly by the application. .. rubric:: NOTES: This structure shall be treated as an opaque data type from the :term:`API` point of view. Members shall not be accessed directly. An entry is initialized by :ref:`InterfaceRtemsInterruptServerEntryInitialize` and destroyed by :ref:`InterfaceRtemsInterruptServerEntryDestroy`. Interrupt server actions can be prepended to the entry by :ref:`InterfaceRtemsInterruptServerActionPrepend`. The entry is submitted to be serviced by :ref:`InterfaceRtemsInterruptServerEntrySubmit`. .. Generated from spec:/rtems/intr/if/server-request .. index:: rtems_interrupt_server_request .. _InterfaceRtemsInterruptServerRequest: rtems_interrupt_server_request ------------------------------ This structure represents an interrupt server request. .. rubric:: MEMBERS: Members of the type shall not be accessed directly by the application. .. rubric:: NOTES: This structure shall be treated as an opaque data type from the :term:`API` point of view. Members shall not be accessed directly. A request is initialized by :ref:`InterfaceRtemsInterruptServerRequestInitialize` and destroyed by :ref:`InterfaceRtemsInterruptServerRequestDestroy`. The interrupt vector of the request can be set by :ref:`InterfaceRtemsInterruptServerRequestSetVector`. The request is submitted to be serviced by :ref:`InterfaceRtemsInterruptServerRequestSubmit`. .. Generated from spec:/rtems/intr/if/signal-variant .. index:: rtems_interrupt_signal_variant .. _InterfaceRtemsInterruptSignalVariant: rtems_interrupt_signal_variant ------------------------------ This enumeration provides interrupt trigger signal variants. .. rubric:: ENUMERATORS: RTEMS_INTERRUPT_UNSPECIFIED_SIGNAL This interrupt signal variant indicates that the interrupt trigger signal is unspecified. RTEMS_INTERRUPT_NO_SIGNAL This interrupt signal variant indicates that the interrupt cannot be triggered by a signal. RTEMS_INTERRUPT_SIGNAL_LEVEL_LOW This interrupt signal variant indicates that the interrupt is triggered by a low level signal. RTEMS_INTERRUPT_SIGNAL_LEVEL_HIGH This interrupt signal variant indicates that the interrupt is triggered by a high level signal. RTEMS_INTERRUPT_SIGNAL_EDGE_FALLING This interrupt signal variant indicates that the interrupt is triggered by a falling edge signal. RTEMS_INTERRUPT_SIGNAL_EDGE_RAISING This interrupt signal variant indicates that the interrupt is triggered by a raising edge signal. .. Generated from spec:/rtems/type/if/interval .. index:: rtems_interval .. _InterfaceRtemsInterval: rtems_interval -------------- This type represents clock tick intervals. .. Generated from spec:/rtems/intr/if/isr .. index:: rtems_isr .. _InterfaceRtemsIsr: rtems_isr --------- This type defines the return type of interrupt service routines. .. rubric:: DESCRIPTION: This type can be used to document interrupt service routines in the source code. .. Generated from spec:/rtems/intr/if/isr-entry .. index:: rtems_isr_entry .. _InterfaceRtemsIsrEntry: rtems_isr_entry --------------- Interrupt service routines installed by :ref:`InterfaceRtemsInterruptCatch` shall have this type. .. Generated from spec:/rtems/message/if/config .. index:: rtems_message_queue_config .. _InterfaceRtemsMessageQueueConfig: rtems_message_queue_config -------------------------- This structure defines the configuration of a message queue constructed by :ref:`InterfaceRtemsMessageQueueConstruct`. .. rubric:: MEMBERS: name This member defines the name of the message queue. maximum_pending_messages This member defines the maximum number of pending messages supported by the message queue. maximum_message_size This member defines the maximum message size supported by the message queue. storage_area This member shall point to the message buffer storage area begin. The message buffer storage area for the message queue shall be an array of the type defined by :ref:`InterfaceRTEMSMESSAGEQUEUEBUFFER` with a maximum message size equal to the maximum message size of this configuration. storage_size This member defines size of the message buffer storage area in bytes. storage_free This member defines the optional handler to free the message buffer storage area. It is called when the message queue is deleted. It is called from task context under protection of the object allocator lock. It is allowed to call :c:func:`free` in this handler. If handler is `NULL `_, then no action will be performed. attributes This member defines the attributes of the message queue. .. Generated from spec:/rtems/mode/if/mode .. index:: rtems_mode .. _InterfaceRtemsMode: rtems_mode ---------- This type represents a Classic API task mode set. .. Generated from spec:/rtems/type/if/mp-packet-classes .. index:: rtems_mp_packet_classes .. _InterfaceRtemsMpPacketClasses: rtems_mp_packet_classes ----------------------- This enumeration defines the MPCI packet classes. .. Generated from spec:/rtems/type/if/mpci-entry .. index:: rtems_mpci_entry .. _InterfaceRtemsMpciEntry: rtems_mpci_entry ---------------- MPCI handler routines shall have this return type. .. Generated from spec:/rtems/type/if/mpci-get-packet-entry .. index:: rtems_mpci_get_packet_entry .. _InterfaceRtemsMpciGetPacketEntry: rtems_mpci_get_packet_entry --------------------------- MPCI get packet routines shall have this type. .. Generated from spec:/rtems/type/if/mpci-initialization-entry .. index:: rtems_mpci_initialization_entry .. _InterfaceRtemsMpciInitializationEntry: rtems_mpci_initialization_entry ------------------------------- MPCI initialization routines shall have this type. .. Generated from spec:/rtems/type/if/mpci-receive-packet-entry .. index:: rtems_mpci_receive_packet_entry .. _InterfaceRtemsMpciReceivePacketEntry: rtems_mpci_receive_packet_entry ------------------------------- MPCI receive packet routines shall have this type. .. Generated from spec:/rtems/type/if/mpci-return-packet-entry .. index:: rtems_mpci_return_packet_entry .. _InterfaceRtemsMpciReturnPacketEntry: rtems_mpci_return_packet_entry ------------------------------ MPCI return packet routines shall have this type. .. Generated from spec:/rtems/type/if/mpci-send-packet-entry .. index:: rtems_mpci_send_packet_entry .. _InterfaceRtemsMpciSendPacketEntry: rtems_mpci_send_packet_entry ---------------------------- MPCI send packet routines shall have this type. .. Generated from spec:/rtems/type/if/mpci-table .. index:: rtems_mpci_table .. _InterfaceRtemsMpciTable: rtems_mpci_table ---------------- This type represents the user-provided MPCI control. .. Generated from spec:/rtems/type/if/multiprocessing-table .. index:: rtems_multiprocessing_table .. _InterfaceRtemsMultiprocessingTable: rtems_multiprocessing_table --------------------------- This type represents the user-provided MPCI configuration. .. Generated from spec:/rtems/type/if/name .. index:: rtems_name .. _InterfaceRtemsName: rtems_name ---------- This type represents Classic API object names. .. rubric:: DESCRIPTION: It is an unsigned 32-bit integer which can be treated as a numeric value or initialized using :ref:`InterfaceRtemsBuildName` to encode four ASCII characters. A value of zero may have a special meaning in some directives. .. Generated from spec:/rtems/object/if/api-class-information .. index:: rtems_object_api_class_information .. _InterfaceRtemsObjectApiClassInformation: rtems_object_api_class_information ---------------------------------- This structure is used to return information to the application about the objects configured for a specific API/Class combination. .. rubric:: MEMBERS: minimum_id This member contains the minimum valid object identifier for this class. maximum_id This member contains the maximum valid object identifier for this class. maximum This member contains the maximum number of active objects configured for this class. auto_extend This member is true, if this class is configured for automatic object extension, otherwise it is false. unallocated This member contains the number of currently inactive objects of this class. .. Generated from spec:/rtems/option/if/option .. index:: rtems_option .. _InterfaceRtemsOption: rtems_option ------------ This type represents a Classic API directive option set. .. Generated from spec:/rtems/type/if/packet-prefix .. index:: rtems_packet_prefix .. _InterfaceRtemsPacketPrefix: rtems_packet_prefix ------------------- This type represents the prefix found at the beginning of each MPCI packet sent between nodes. .. Generated from spec:/rtems/ratemon/if/period-states .. index:: rtems_rate_monotonic_period_states .. _InterfaceRtemsRateMonotonicPeriodStates: rtems_rate_monotonic_period_states ---------------------------------- This enumeration defines the states in which a period may be. .. rubric:: ENUMERATORS: RATE_MONOTONIC_INACTIVE This status indicates the period is off the watchdog chain, and has never been initialized. RATE_MONOTONIC_ACTIVE This status indicates the period is on the watchdog chain, and running. The owner may be executing or blocked waiting on another object. RATE_MONOTONIC_EXPIRED This status indicates the period is off the watchdog chain, and has expired. The owner may still execute and has taken too much time to complete this iteration of the period. .. Generated from spec:/rtems/ratemon/if/period-statistics .. index:: rtems_rate_monotonic_period_statistics .. _InterfaceRtemsRateMonotonicPeriodStatistics: rtems_rate_monotonic_period_statistics -------------------------------------- This structure provides the statistics of a period. .. rubric:: MEMBERS: count This member contains the number of periods executed. missed_count This member contains the number of periods missed. min_cpu_time This member contains the least amount of processor time used in a period. max_cpu_time This member contains the highest amount of processor time used in a period. total_cpu_time This member contains the total amount of processor time used in a period. min_wall_time This member contains the least amount of :term:`CLOCK_MONOTONIC` time used in a period. max_wall_time This member contains the highest amount of :term:`CLOCK_MONOTONIC` time used in a period. total_wall_time This member contains the total amount of :term:`CLOCK_MONOTONIC` time used in a period. .. Generated from spec:/rtems/ratemon/if/period-status .. index:: rtems_rate_monotonic_period_status .. _InterfaceRtemsRateMonotonicPeriodStatus: rtems_rate_monotonic_period_status ---------------------------------- This structure provides the detailed status of a period. .. rubric:: MEMBERS: owner This member contains the identifier of the owner task of the period. state This member contains the state of the period. since_last_period This member contains the time elapsed since the last successful invocation :ref:`InterfaceRtemsRateMonotonicPeriod` using :term:`CLOCK_MONOTONIC`. If the period is expired or has not been initiated, then this value has no meaning. executed_since_last_period This member contains the processor time consumed by the owner task since the last successful invocation :ref:`InterfaceRtemsRateMonotonicPeriod`. If the period is expired or has not been initiated, then this value has no meaning. postponed_jobs_count This member contains the count of jobs which are not released yet. .. Handwritten .. index:: rtems_regulator_attributes .. _InterfaceRtemsRegulatorAttributes: rtems_regulator_attributes -------------------------- This structure defines the configuration of a regulator created by :ref:`InterfaceRtemsRegulatorCreate`. .. rubric:: MEMBERS: deliverer This member contains a pointer to an application function invoked by the Delivery thread to output a message to the destination. deliverer_context This member contains a pointer to an application defined context which is passed to delivery function. maximum_message_size This member contains the maximum size message to process. maximum_messages This member contains the maximum number of messages to be able to buffer. output_thread_priority This member contains the priority of output thread. output_thread_stack_size This member contains the Stack size of output thread. output_thread_period This member contains the period (in ticks) of output thread. maximum_to_dequeue_per_period This member contains the maximum number of messages the output thread should dequeue and deliver per period. .. rubric:: NOTES: This type is passed as an argument to :ref:`InterfaceRtemsRegulatorCreate`. .. Handwritten .. index:: rtems_regulator_deliverer .. _InterfaceRtemsRegulatorDeliverer: rtems_regulator_deliverer ------------------------- This type represents the function signature used to specify a delivery function for the RTEMS Regulator. .. rubric:: NOTES: This type is used in the :ref:`InterfaceRtemsRegulatorAttributes` structure which is passed as an argument to :ref:`InterfaceRtemsRegulatorCreate`. .. Handwritten .. index:: rtems_regulator_statistics .. _InterfaceRtemsRegulatorStatistics: rtems_regulator_statistics -------------------------- This structure defines the statistics maintained by each Regulator instance. .. rubric:: MEMBERS: obtained This member contains the number of successfully obtained buffers. released This member contains the number of successfully released buffers. delivered This member contains the number of successfully delivered buffers. period_statistics This member contains the Rate Monotonic Period statistics for the Delivery Thread. It is an instance of the :ref:`InterfaceRtemsRateMonotonicPeriodStatistics` structure. .. rubric:: NOTES: This type is passed as an argument to :ref:`InterfaceRtemsRegulatorGetStatistics`. .. Generated from spec:/rtems/signal/if/set .. index:: rtems_signal_set .. _InterfaceRtemsSignalSet: rtems_signal_set ---------------- This integer type represents a bit field which can hold exactly 32 individual signals. .. Generated from spec:/rtems/config/if/stack-allocate-hook .. index:: rtems_stack_allocate_hook .. _InterfaceRtemsStackAllocateHook: rtems_stack_allocate_hook ------------------------- A thread stack allocator allocate handler shall have this type. .. Generated from spec:/rtems/config/if/stack-allocate-init-hook .. index:: rtems_stack_allocate_init_hook .. _InterfaceRtemsStackAllocateInitHook: rtems_stack_allocate_init_hook ------------------------------ A task stack allocator initialization handler shall have this type. .. Generated from spec:/rtems/config/if/stack-free-hook .. index:: rtems_stack_free_hook .. _InterfaceRtemsStackFreeHook: rtems_stack_free_hook --------------------- A task stack allocator free handler shall have this type. .. Generated from spec:/rtems/status/if/code .. index:: rtems_status_code .. _InterfaceRtemsStatusCode: rtems_status_code ----------------- This enumeration provides status codes for directives of the Classic API. .. rubric:: ENUMERATORS: RTEMS_SUCCESSFUL This status code indicates successful completion of a requested operation. RTEMS_TASK_EXITTED This status code indicates that a thread exitted. RTEMS_MP_NOT_CONFIGURED This status code indicates that multiprocessing was not configured. RTEMS_INVALID_NAME This status code indicates that an object name was invalid. RTEMS_INVALID_ID This status code indicates that an object identifier was invalid. RTEMS_TOO_MANY This status code indicates you have attempted to create too many instances of a particular object class. RTEMS_TIMEOUT This status code indicates that a blocking directive timed out. RTEMS_OBJECT_WAS_DELETED This status code indicates the object was deleted while the thread was blocked waiting. RTEMS_INVALID_SIZE This status code indicates that a specified size was invalid. RTEMS_INVALID_ADDRESS This status code indicates that a specified address was invalid. RTEMS_INVALID_NUMBER This status code indicates that a specified number was invalid. RTEMS_NOT_DEFINED This status code indicates that the item has not been initialized. RTEMS_RESOURCE_IN_USE This status code indicates that the object still had resources in use. RTEMS_UNSATISFIED This status code indicates that the request was not satisfied. RTEMS_INCORRECT_STATE This status code indicates that an object was in wrong state for the requested operation. RTEMS_ALREADY_SUSPENDED This status code indicates that the thread was already suspended. RTEMS_ILLEGAL_ON_SELF This status code indicates that the operation was illegal on the calling thread. RTEMS_ILLEGAL_ON_REMOTE_OBJECT This status code indicates that the operation was illegal on a remote object. RTEMS_CALLED_FROM_ISR This status code indicates that the operation should not be called from this execution environment. RTEMS_INVALID_PRIORITY This status code indicates that an invalid thread priority was provided. RTEMS_INVALID_CLOCK This status code indicates that a specified date or time was invalid. RTEMS_INVALID_NODE This status code indicates that a specified node identifier was invalid. RTEMS_NOT_CONFIGURED This status code indicates that the directive was not configured. RTEMS_NOT_OWNER_OF_RESOURCE This status code indicates that the caller was not the owner of the resource. RTEMS_NOT_IMPLEMENTED This status code indicates the directive or requested portion of the directive is not implemented. This is a hint that you have stumbled across an opportunity to submit code to the RTEMS Project. RTEMS_INTERNAL_ERROR This status code indicates that an internal RTEMS inconsistency was detected. RTEMS_NO_MEMORY This status code indicates that the directive attempted to allocate memory but was unable to do so. RTEMS_IO_ERROR This status code indicates a device driver IO error. RTEMS_INTERRUPTED This status code is used internally by the implementation to indicate a blocking device driver call has been interrupted and should be reflected to the caller as interrupted. RTEMS_PROXY_BLOCKING This status code is used internally by the implementation when performing operations on behalf of remote tasks. This is referred to as proxying operations and this status indicates that the operation could not be completed immediately and the proxy is blocking. .. Generated from spec:/rtems/task/if/task .. index:: rtems_task .. _InterfaceRtemsTask: rtems_task ---------- This type defines the return type of task entry points. .. rubric:: DESCRIPTION: This type can be used to document task entry points in the source code. .. Generated from spec:/rtems/task/if/argument .. index:: rtems_task_argument .. _InterfaceRtemsTaskArgument: rtems_task_argument ------------------- This integer type represents task argument values. .. rubric:: NOTES: The type is an architecture-specific unsigned integer type which is large enough to represent pointer values and 32-bit unsigned integers. .. Generated from spec:/rtems/userext/if/task-begin .. index:: rtems_task_begin_extension .. _InterfaceRtemsTaskBeginExtension: rtems_task_begin_extension -------------------------- Task begin extensions are invoked when a task begins execution. .. rubric:: NOTES: The task begin extensions are invoked in :term:`extension forward order`. Task begin extensions are invoked with thread dispatching enabled. This allows the use of dynamic memory allocation, creation of POSIX keys, and use of C++ thread-local storage. Blocking synchronization primitives are allowed also. The task begin extensions are invoked before the global construction. The task begin extensions may be called as a result of a task restart through :ref:`InterfaceRtemsTaskRestart`. .. Generated from spec:/rtems/task/if/config .. index:: rtems_task_config .. _InterfaceRtemsTaskConfig: rtems_task_config ----------------- This structure defines the configuration of a task constructed by :ref:`InterfaceRtemsTaskConstruct`. .. rubric:: MEMBERS: name This member defines the name of the task. initial_priority This member defines the initial priority of the task. storage_area This member shall point to the task storage area begin. The task storage area will contain the task stack, the thread-local storage, and the floating-point context on architectures with a separate floating-point context. The task storage area begin address and size should be aligned by :c:macro:`RTEMS_TASK_STORAGE_ALIGNMENT`. To avoid memory waste, use :c:func:`RTEMS_ALIGNED` and :c:macro:`RTEMS_TASK_STORAGE_ALIGNMENT` to enforce the recommended alignment of a statically allocated task storage area. storage_size This member defines size of the task storage area in bytes. Use the :ref:`InterfaceRTEMSTASKSTORAGESIZE` macro to determine the recommended task storage area size. maximum_thread_local_storage_size This member defines the maximum thread-local storage size supported by the task storage area. Use :c:func:`RTEMS_ALIGN_UP` and :c:macro:`RTEMS_TASK_STORAGE_ALIGNMENT` to adjust the size to meet the minimum alignment requirement of a thread-local storage area used to construct a task. If the value is less than the actual thread-local storage size, then the task construction by :ref:`InterfaceRtemsTaskConstruct` fails. If the is less than the task storage area size, then the task construction by :ref:`InterfaceRtemsTaskConstruct` fails. The actual thread-local storage size is determined when the application executable is linked. The ``rtems-exeinfo`` command line tool included in the RTEMS Tools can be used to obtain the thread-local storage size and alignment of an application executable. The application may configure the maximum thread-local storage size for all threads explicitly through the :ref:`CONFIGURE_MAXIMUM_THREAD_LOCAL_STORAGE_SIZE` configuration option. storage_free This member defines the optional handler to free the task storage area. It is called on exactly two mutually exclusive occasions. Firstly, when the task construction aborts due to a failed task create extension, or secondly, when the task is deleted. It is called from task context under protection of the object allocator lock. It is allowed to call :c:func:`free` in this handler. If handler is `NULL `_, then no action will be performed. initial_modes This member defines the initial modes of the task. attributes This member defines the attributes of the task. .. Generated from spec:/rtems/userext/if/task-create .. index:: rtems_task_create_extension .. _InterfaceRtemsTaskCreateExtension: rtems_task_create_extension --------------------------- Task create extensions are invoked when a task is created. .. rubric:: NOTES: The task create extensions are invoked in :term:`extension forward order`. The task create extensions are invoked after a new task has been completely initialized, but before it is started. While normal tasks are created, the executing thread is the owner of the object allocator mutex. The object allocator mutex allows nesting, so the normal memory allocation routines can be used allocate memory for the created thread. If the task create extension returns :c:macro:`false`, then the task create operation stops immediately and the entire task create operation will fail. In this case, all task delete extensions are invoked, see :ref:`InterfaceRtemsTaskDeleteExtension`. .. Generated from spec:/rtems/userext/if/task-delete .. index:: rtems_task_delete_extension .. _InterfaceRtemsTaskDeleteExtension: rtems_task_delete_extension --------------------------- Task delete extensions are invoked when a task is deleted. .. rubric:: NOTES: The task delete extensions are invoked in :term:`extension reverse order`. The task delete extensions are invoked by task create directives before an attempt to allocate a :term:`TCB` is made. If a task create extension failed, then a task delete extension may be invoked without a previous invocation of the corresponding task create extension of the extension set. .. Generated from spec:/rtems/task/if/entry .. index:: rtems_task_entry .. _InterfaceRtemsTaskEntry: rtems_task_entry ---------------- This type defines the :term:`task entry` point of an RTEMS task. .. Generated from spec:/rtems/userext/if/task-exitted .. index:: rtems_task_exitted_extension .. _InterfaceRtemsTaskExittedExtension: rtems_task_exitted_extension ---------------------------- Task exitted extensions are invoked when a task entry returns. .. rubric:: NOTES: The task exitted extensions are invoked in :term:`extension forward order`. .. Generated from spec:/rtems/type/if/priority .. index:: rtems_task_priority .. _InterfaceRtemsTaskPriority: rtems_task_priority ------------------- This integer type represents task priorities of the Classic API. .. Generated from spec:/rtems/userext/if/task-restart .. index:: rtems_task_restart_extension .. _InterfaceRtemsTaskRestartExtension: rtems_task_restart_extension ---------------------------- Task restart extensions are invoked when a task restarts. .. rubric:: NOTES: The task restart extensions are invoked in :term:`extension forward order`. The task restart extensions are invoked in the context of the restarted thread right before the execution context is reloaded. The thread stack reflects the previous execution context. Thread restart and delete requests issued by restart extensions lead to recursion. .. Generated from spec:/rtems/userext/if/task-start .. index:: rtems_task_start_extension .. _InterfaceRtemsTaskStartExtension: rtems_task_start_extension -------------------------- Task start extensions are invoked when a task was made ready for the first time. .. rubric:: NOTES: The task start extensions are invoked in :term:`extension forward order`. In SMP configurations, the thread may already run on another processor before the task start extensions are actually invoked. Task switch and task begin extensions may run before or in parallel with the thread start extension in SMP configurations, see :ref:`InterfaceRtemsTaskSwitchExtension` and :ref:`InterfaceRtemsTaskBeginExtension`. .. Generated from spec:/rtems/userext/if/task-switch .. index:: rtems_task_switch_extension .. _InterfaceRtemsTaskSwitchExtension: rtems_task_switch_extension --------------------------- Task switch extensions are invoked when a thread switch from an executing thread to a heir thread takes place. .. rubric:: NOTES: The task switch extensions are invoked in :term:`extension forward order`. The invocation conditions of the task switch extensions depend on whether RTEMS was built with SMP support enabled or disabled. A user must pay attention to the differences to correctly implement a task switch extension. Where the system was built with SMP support disabled, the task switch extensions are invoked before the context switch from the currently executing thread to the heir thread. The executing is a pointer to the :term:`TCB` of the currently executing thread. The heir is a pointer to the TCB of the heir thread. The context switch initiated through the multitasking start is not covered by the task switch extensions. Where the system was built with SMP support enabled, the task switch extensions are invoked after the context switch to the heir thread. The executing is a pointer to the TCB of the previously executing thread. Despite the name, this is not the currently executing thread. The heir is a pointer to the TCB of the newly executing thread. This is the currently executing thread. The context switches initiated through the multitasking start are covered by the task switch extensions. The reason for the differences to uniprocessor configurations is that the context switch may update the heir thread of the processor. The task switch extensions are invoked with maskable interrupts disabled and with ownership of a processor-specific SMP lock. Task switch extensions may run in parallel on multiple processors. It is recommended to use thread-local or processor-specific data structures for task switch extensions. A global SMP lock should be avoided for performance reasons, see :ref:`InterfaceRtemsInterruptLockInitialize`. .. Generated from spec:/rtems/userext/if/task-terminate .. index:: rtems_task_terminate_extension .. _InterfaceRtemsTaskTerminateExtension: rtems_task_terminate_extension ------------------------------ Task terminate extensions are invoked when a task terminates. .. rubric:: NOTES: The task terminate extensions are invoked in :term:`extension reverse order`. The task terminate extensions are invoked in the context of the terminating thread right before the thread dispatch to the heir thread should take place. The thread stack reflects the previous execution context. The POSIX cleanup and key destructors execute in this context. Thread restart and delete requests issued by terminate extensions lead to recursion. .. Generated from spec:/rtems/task/if/visitor .. index:: rtems_task_visitor .. _InterfaceRtemsTaskVisitor: rtems_task_visitor ------------------ Visitor routines invoked by :ref:`InterfaceRtemsTaskIterate` shall have this type. .. Generated from spec:/rtems/task/if/tcb .. index:: rtems_tcb .. _InterfaceRtemsTcb: rtems_tcb --------- This structure represents the :term:`TCB`. .. Generated from spec:/rtems/type/if/time-of-day .. index:: rtems_time_of_day .. _InterfaceRtemsTimeOfDay: rtems_time_of_day ----------------- This type represents Classic API calendar times. .. rubric:: MEMBERS: year This member contains the year A.D. month This member contains the month of the year with values from 1 to 12. day This member contains the day of the month with values from 1 to 31. hour This member contains the hour of the day with values from 0 to 23. minute This member contains the minute of the hour with values from 0 to 59. second This member contains the second of the minute with values from 0 to 59. ticks This member contains the clock tick of the second with values from 0 to :ref:`InterfaceRtemsClockGetTicksPerSecond` minus one. .. Generated from spec:/rtems/timer/if/information .. index:: rtems_timer_information .. _InterfaceRtemsTimerInformation: rtems_timer_information ----------------------- The structure contains information about a timer. .. rubric:: MEMBERS: the_class The timer class member indicates how the timer was most recently fired. initial This member indicates the initial requested interval. start_time This member indicates the time the timer was initially scheduled. The time is in clock ticks since the clock driver initialization or the last clock tick counter overflow. stop_time This member indicates the time the timer was scheduled to fire. The time is in clock ticks since the clock driver initialization or the last clock tick counter overflow. .. Generated from spec:/rtems/timer/if/service-routine .. index:: rtems_timer_service_routine .. _InterfaceRtemsTimerServiceRoutine: rtems_timer_service_routine --------------------------- This type defines the return type of routines which can be fired by directives of the Timer Manager. .. rubric:: DESCRIPTION: This type can be used to document timer service routines in the source code. .. Generated from spec:/rtems/timer/if/service-routine-entry .. index:: rtems_timer_service_routine_entry .. _InterfaceRtemsTimerServiceRoutineEntry: rtems_timer_service_routine_entry --------------------------------- This type defines the prototype of routines which can be fired by directives of the Timer Manager. .. Generated from spec:/rtems/intr/if/vector-number .. index:: rtems_vector_number .. _InterfaceRtemsVectorNumber: rtems_vector_number ------------------- This integer type represents interrupt vector numbers.