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/**
* @file
*
* @ingroup RTEMSAPIProfiling
*
* @brief This header file provides the Profiling Support API.
*/
/*
* Copyright (c) 2014 embedded brains GmbH. All rights reserved.
*
* embedded brains GmbH
* Dornierstr. 4
* 82178 Puchheim
* Germany
* <rtems@embedded-brains.de>
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://www.rtems.org/license/LICENSE.
*/
#ifndef _RTEMS_PROFILING_H
#define _RTEMS_PROFILING_H
#include <stdint.h>
#include <rtems/print.h>
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
/**
* @defgroup RTEMSAPIProfiling Profiling Support
*
* @ingroup RTEMSAPI
*
* @brief The profiling support offers functions to report profiling
* information available in the system.
*
* Profiling support is by default disabled. It must be enabled via the
* configure command line with the <tt>--enable-profiling</tt> option. In this
* case the RTEMS_PROFILING pre-processor symbol is defined and profiling
* statistics will be gathered during system run-time. The profiling support
* increases the time of critical sections and has some memory overhead. The
* overhead should be acceptable for most applications. The aim of the
* profiling implementation is to be available even for production systems so
* that verification is simplified.
*
* Profiling information includes critical timing values such as the maximum
* time of disabled thread dispatching which is a measure for the thread
* dispatch latency. On SMP configurations statistics of all SMP locks in the
* system are available.
*
* Profiling information can be retrieved via rtems_profiling_iterate() and
* reported as an XML dump via rtems_profiling_report_xml(). These functions
* are always available, but actual profiling data is only available if enabled
* at build configuration time.
*
* @{
*/
/**
* @brief Type of profiling data.
*/
typedef enum {
/**
* @brief Type of per-CPU profiling data.
*
* @see rtems_profiling_per_cpu.
*/
RTEMS_PROFILING_PER_CPU,
/**
* @brief Type of SMP lock profiling data.
*
* @see rtems_profiling_smp_lock.
*/
RTEMS_PROFILING_SMP_LOCK
} rtems_profiling_type;
/**
* @brief The profiling data header.
*/
typedef struct {
/**
* @brief The profiling data type.
*/
rtems_profiling_type type;
} rtems_profiling_header;
/**
* @brief Per-CPU profiling data.
*
* Theoretically all values in this structure can overflow, but the integer
* types are chosen so that they cannot overflow in practice. On systems with
* a 1GHz CPU counter, the 64-bit integers can overflow in about 58 years.
* Since the system should not spend most of the time in critical sections the
* actual system run-time is much longer. Several other counters in the system
* will overflow before we get a problem in the profiling area.
*/
typedef struct {
/**
* @brief The profiling data header.
*/
rtems_profiling_header header;
/**
* @brief The processor index of this profiling data.
*/
uint32_t processor_index;
/**
* @brief The maximum time of disabled thread dispatching in nanoseconds.
*/
uint32_t max_thread_dispatch_disabled_time;
/**
* @brief Count of times when the thread dispatch disable level changes from
* zero to one in thread context.
*
* This value may overflow.
*/
uint64_t thread_dispatch_disabled_count;
/**
* @brief Total time of disabled thread dispatching in nanoseconds.
*
* The average time of disabled thread dispatching is the total time of
* disabled thread dispatching divided by the thread dispatch disabled
* count.
*
* This value may overflow.
*/
uint64_t total_thread_dispatch_disabled_time;
/**
* @brief The maximum interrupt delay in nanoseconds if supported by the
* hardware.
*
* The interrupt delay is the time interval from the recognition of an
* interrupt signal by the hardware up to the execution start of the
* corresponding high-level handler. The interrupt delay is the main
* contributor to the interrupt latency. To measure this time hardware
* support is required. A time stamp unit must capture the interrupt signal
* recognition time. If no hardware support is available, then this field
* will have a constant value of zero.
*/
uint32_t max_interrupt_delay;
/**
* @brief The maximum time spent to process a single sequence of nested
* interrupts in nanoseconds.
*
* This is the time interval between the change of the interrupt nest level
* from zero to one and the change back from one to zero. It is the measured
* worst-case execution time of interrupt service routines. Please note that
* in case of nested interrupts this time includes the combined execution
* time and not the maximum time of an individual interrupt service routine.
*/
uint32_t max_interrupt_time;
/**
* @brief Count of times when the interrupt nest level changes from zero to
* one.
*
* This value may overflow.
*/
uint64_t interrupt_count;
/**
* @brief Total time of interrupt processing in nanoseconds.
*
* The average time of interrupt processing is the total time of interrupt
* processing divided by the interrupt count.
*
* This value may overflow.
*/
uint64_t total_interrupt_time;
} rtems_profiling_per_cpu;
/**
* @brief Count of lock contention counters for SMP lock profiling.
*/
#define RTEMS_PROFILING_SMP_LOCK_CONTENTION_COUNTS 4
/**
* @brief SMP lock profiling data.
*
* The lock acquire attempt instant is the point in time right after the
* interrupt disable action in the lock acquire sequence.
*
* The lock acquire instant is the point in time right after the lock
* acquisition. This is the begin of the critical section code execution.
*
* The lock acquire time is the time elapsed between the lock acquire attempt
* instant and the lock acquire instant.
*
* The lock release instant is the point in time right before the interrupt
* enable action in the lock release sequence.
*
* The lock section time is the time elapsed between the lock acquire instant
* and the lock release instant.
*/
typedef struct {
/**
* @brief The profiling data header.
*/
rtems_profiling_header header;
/**
* @brief The lock name.
*/
const char *name;
/**
* @brief The maximum lock acquire time in nanoseconds.
*/
uint32_t max_acquire_time;
/**
* @brief The maximum lock section time in nanoseconds.
*/
uint32_t max_section_time;
/**
* @brief The count of lock uses.
*
* This value may overflow.
*/
uint64_t usage_count;
/**
* @brief Total lock acquire time in nanoseconds.
*
* The average lock acquire time is the total acquire time divided by the
* lock usage count. The ration of the total section and total acquire times
* gives a measure for the lock contention.
*
* This value may overflow.
*/
uint64_t total_acquire_time;
/**
* @brief Total lock section time in nanoseconds.
*
* The average lock section time is the total section time divided by the
* lock usage count.
*
* This value may overflow.
*/
uint64_t total_section_time;
/**
* @brief The counts of lock acquire operations by contention.
*
* The contention count for index N corresponds to a lock acquire attempt
* with an initial queue length of N. The last index corresponds to all
* lock acquire attempts with an initial queue length greater than or equal
* to RTEMS_PROFILING_SMP_LOCK_CONTENTION_COUNTS minus one.
*
* The values may overflow.
*/
uint64_t contention_counts[RTEMS_PROFILING_SMP_LOCK_CONTENTION_COUNTS];
} rtems_profiling_smp_lock;
/**
* @brief Collection of profiling data.
*/
typedef union {
/**
* @brief Header to specify the actual profiling data.
*/
rtems_profiling_header header;
/**
* @brief Per-CPU profiling data if indicated by the header.
*/
rtems_profiling_per_cpu per_cpu;
/**
* @brief SMP lock profiling data if indicated by the header.
*/
rtems_profiling_smp_lock smp_lock;
} rtems_profiling_data;
/**
* @brief Visitor function for the profiling iteration.
*
* @param[in, out] arg The visitor argument.
* @param[in] data The current profiling data.
*
* @see rtems_profiling_iterate().
*/
typedef void (*rtems_profiling_visitor)(
void *arg,
const rtems_profiling_data *data
);
/**
* @brief Iterates through all profiling data of the system.
*
* @param[in] visitor The visitor.
* @param[in, out] visitor_arg The visitor argument.
*/
void rtems_profiling_iterate(
rtems_profiling_visitor visitor,
void *visitor_arg
);
/**
* @brief Reports profiling data as XML.
*
* @param[in] name The name of the profiling report.
* @param[in] printer The RTEMS printer to send the output too.
* @param[in] indentation_level The current indentation level.
* @param[in] indentation The string used for indentation.
*
* @returns As specified by printf().
*/
int rtems_profiling_report_xml(
const char *name,
const rtems_printer *printer,
uint32_t indentation_level,
const char *indentation
);
/** @} */
#ifdef __cplusplus
}
#endif /* __cplusplus */
#endif /* _RTEMS_PROFILING_H */
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