/* SPDX-License-Identifier: BSD-2-Clause */ /** * @file * * @ingroup RtemsSemValPerf */ /* * Copyright (C) 2021 embedded brains GmbH & Co. KG * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ /* * 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 */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include "tx-support.h" #include /** * @defgroup RtemsSemValPerf spec:/rtems/sem/val/perf * * @ingroup TestsuitesPerformanceNoClock0 * * @brief This test case provides a context to run @ref RTEMSAPIClassicSem * performance tests. * * @{ */ /** * @brief Test context for spec:/rtems/sem/val/perf test case. */ typedef struct { /** * @brief This member provides a mutex identifier. */ rtems_id mutex_id; /** * @brief This member provides a worker identifier. */ rtems_id worker_id; /** * @brief This member provides a status code. */ rtems_status_code status; /** * @brief This member references the measure runtime context. */ T_measure_runtime_context *context; /** * @brief This member provides the measure runtime request. */ T_measure_runtime_request request; /** * @brief This member provides an optional measurement begin time point. */ T_ticks begin; /** * @brief This member provides an optional measurement end time point. */ T_ticks end; } RtemsSemValPerf_Context; static RtemsSemValPerf_Context RtemsSemValPerf_Instance; #define EVENT_END RTEMS_EVENT_0 #define EVENT_OBTAIN RTEMS_EVENT_1 #define EVENT_OBTAIN_END RTEMS_EVENT_2 #define EVENT_RELEASE RTEMS_EVENT_3 #define EVENT_RELEASE_END RTEMS_EVENT_4 typedef RtemsSemValPerf_Context Context; static void Send( const Context *ctx, rtems_event_set events ) { SendEvents( ctx->worker_id, events ); } static void Worker( rtems_task_argument arg ) { Context *ctx; ctx = (Context *) arg; while ( true ) { rtems_event_set events; rtems_status_code sc; T_ticks ticks; sc = rtems_event_receive( RTEMS_ALL_EVENTS, RTEMS_EVENT_ANY | RTEMS_WAIT, RTEMS_NO_TIMEOUT, &events ); ticks = T_tick(); T_quiet_rsc_success( sc ); if ( ( events & EVENT_END ) != 0 ) { ctx->end = ticks; } if ( ( events & EVENT_OBTAIN ) != 0 ) { sc = rtems_semaphore_obtain( ctx->mutex_id, RTEMS_WAIT, RTEMS_NO_TIMEOUT ); ticks = T_tick(); T_quiet_rsc_success( sc ); if ( ( events & EVENT_OBTAIN_END ) != 0 ) { ctx->end = ticks; } } if ( ( events & EVENT_RELEASE ) != 0 ) { sc = rtems_semaphore_release( ctx->mutex_id ); ticks = T_tick(); T_quiet_rsc_success( sc ); if ( ( events & EVENT_RELEASE_END ) != 0 ) { ctx->end = ticks; } } } } static void RtemsSemValPerf_Setup_Context( RtemsSemValPerf_Context *ctx ) { T_measure_runtime_config config; memset( &config, 0, sizeof( config ) ); config.sample_count = 100; ctx->request.arg = ctx; ctx->request.flags = T_MEASURE_RUNTIME_REPORT_SAMPLES; ctx->context = T_measure_runtime_create( &config ); T_assert_not_null( ctx->context ); } /** * @brief Create a mutex and a worker task. */ static void RtemsSemValPerf_Setup( RtemsSemValPerf_Context *ctx ) { SetSelfPriority( PRIO_NORMAL ); ctx->mutex_id = CreateMutex(); ctx->worker_id = CreateTask( "WORK", PRIO_HIGH ); StartTask( ctx->worker_id, Worker, ctx ); } static void RtemsSemValPerf_Setup_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemValPerf_Setup_Context( ctx ); RtemsSemValPerf_Setup( ctx ); } /** * @brief Delete the worker task and the mutex. */ static void RtemsSemValPerf_Teardown( RtemsSemValPerf_Context *ctx ) { DeleteTask( ctx->worker_id ); DeleteMutex( ctx->mutex_id ); RestoreRunnerPriority(); } static void RtemsSemValPerf_Teardown_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemValPerf_Teardown( ctx ); } static T_fixture RtemsSemValPerf_Fixture = { .setup = RtemsSemValPerf_Setup_Wrap, .stop = NULL, .teardown = RtemsSemValPerf_Teardown_Wrap, .scope = NULL, .initial_context = &RtemsSemValPerf_Instance }; /** * @defgroup RtemsSemReqPerfMtxPiObtain spec:/rtems/sem/req/perf-mtx-pi-obtain * * @{ */ /** * @brief Obtain the available mutex. */ static void RtemsSemReqPerfMtxPiObtain_Body( RtemsSemValPerf_Context *ctx ) { ctx->status = rtems_semaphore_obtain( ctx->mutex_id, RTEMS_WAIT, RTEMS_NO_TIMEOUT ); } static void RtemsSemReqPerfMtxPiObtain_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiObtain_Body( ctx ); } /** * @brief Release the mutex. Discard samples interrupted by a clock tick. */ static bool RtemsSemReqPerfMtxPiObtain_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc_success( ctx->status ); ReleaseMutex( ctx->mutex_id ); return tic == toc; } static bool RtemsSemReqPerfMtxPiObtain_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiObtain_Teardown( ctx, delta, tic, toc, retry ); } /** @} */ /** * @defgroup RtemsSemReqPerfMtxPiRelease \ * spec:/rtems/sem/req/perf-mtx-pi-release * * @{ */ /** * @brief Obtain the mutex. */ static void RtemsSemReqPerfMtxPiRelease_Setup( RtemsSemValPerf_Context *ctx ) { ObtainMutex( ctx->mutex_id ); } static void RtemsSemReqPerfMtxPiRelease_Setup_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiRelease_Setup( ctx ); } /** * @brief Release the mutex. */ static void RtemsSemReqPerfMtxPiRelease_Body( RtemsSemValPerf_Context *ctx ) { ctx->status = rtems_semaphore_release( ctx->mutex_id ); } static void RtemsSemReqPerfMtxPiRelease_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiRelease_Body( ctx ); } /** * @brief Discard samples interrupted by a clock tick. */ static bool RtemsSemReqPerfMtxPiRelease_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc_success( ctx->status ); return tic == toc; } static bool RtemsSemReqPerfMtxPiRelease_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiRelease_Teardown( ctx, delta, tic, toc, retry ); } /** @} */ /** * @defgroup RtemsSemReqPerfMtxPiReleaseOne \ * spec:/rtems/sem/req/perf-mtx-pi-release-one * * @{ */ /** * @brief Let one task wait on the mutex. */ static void RtemsSemReqPerfMtxPiReleaseOne_Setup( RtemsSemValPerf_Context *ctx ) { SetSelfPriority( PRIO_HIGH ); ObtainMutex( ctx->mutex_id ); Send( ctx, EVENT_OBTAIN ); Yield(); Send( ctx, EVENT_RELEASE ); } static void RtemsSemReqPerfMtxPiReleaseOne_Setup_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiReleaseOne_Setup( ctx ); } /** * @brief Release the mutex. */ static void RtemsSemReqPerfMtxPiReleaseOne_Body( RtemsSemValPerf_Context *ctx ) { /* * The release will unblock the worker task which has our priority. The * scheduler ensures FIFO ordering for ready threads of the same priority, so * the release will not preempt us. */ ctx->status = rtems_semaphore_release( ctx->mutex_id ); } static void RtemsSemReqPerfMtxPiReleaseOne_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiReleaseOne_Body( ctx ); } /** * @brief Restore the worker priority. Discard samples interrupted by a clock * tick. */ static bool RtemsSemReqPerfMtxPiReleaseOne_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc( ctx->status, RTEMS_SUCCESSFUL ); SetSelfPriority( PRIO_NORMAL ); return tic == toc; } static bool RtemsSemReqPerfMtxPiReleaseOne_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiReleaseOne_Teardown( ctx, delta, tic, toc, retry ); } /** @} */ #if defined(RTEMS_SMP) /** * @defgroup RtemsSemReqPerfMtxPiReleaseOtherCpu \ * spec:/rtems/sem/req/perf-mtx-pi-release-other-cpu * * @{ */ /** * @brief Move worker to scheduler B. */ static void RtemsSemReqPerfMtxPiReleaseOtherCpu_Prepare( RtemsSemValPerf_Context *ctx ) { SetScheduler( ctx->worker_id, SCHEDULER_B_ID, PRIO_NORMAL ); } /** * @brief Let one task wait on the mutex. */ static void RtemsSemReqPerfMtxPiReleaseOtherCpu_Setup( RtemsSemValPerf_Context *ctx ) { ObtainMutex( ctx->mutex_id ); Send( ctx, EVENT_OBTAIN | EVENT_OBTAIN_END | EVENT_RELEASE ); WaitForNextTask( 1, ctx->worker_id ); } static void RtemsSemReqPerfMtxPiReleaseOtherCpu_Setup_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiReleaseOtherCpu_Setup( ctx ); } /** * @brief Release the mutex. */ static void RtemsSemReqPerfMtxPiReleaseOtherCpu_Body( RtemsSemValPerf_Context *ctx ) { ctx->begin = T_tick(); ctx->status = rtems_semaphore_release( ctx->mutex_id ); } static void RtemsSemReqPerfMtxPiReleaseOtherCpu_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiReleaseOtherCpu_Body( ctx ); } /** * @brief Make sure the worker waits for the next event. Set the measured * runtime. Discard samples interrupted by a clock tick. */ static bool RtemsSemReqPerfMtxPiReleaseOtherCpu_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc( ctx->status, RTEMS_SUCCESSFUL ); WaitForNextTask( 1, ctx->worker_id ); *delta = ctx->end - ctx->begin; return tic == toc; } static bool RtemsSemReqPerfMtxPiReleaseOtherCpu_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiReleaseOtherCpu_Teardown( ctx, delta, tic, toc, retry ); } /** * @brief Move worker to scheduler A. */ static void RtemsSemReqPerfMtxPiReleaseOtherCpu_Cleanup( RtemsSemValPerf_Context *ctx ) { SetScheduler( ctx->worker_id, SCHEDULER_A_ID, PRIO_HIGH ); } /** @} */ #endif /** * @defgroup RtemsSemReqPerfMtxPiReleasePreempt \ * spec:/rtems/sem/req/perf-mtx-pi-release-preempt * * @{ */ /** * @brief Let one task wait on the mutex. */ static void RtemsSemReqPerfMtxPiReleasePreempt_Setup( RtemsSemValPerf_Context *ctx ) { ObtainMutex( ctx->mutex_id ); Send( ctx, EVENT_OBTAIN | EVENT_OBTAIN_END | EVENT_RELEASE ); } static void RtemsSemReqPerfMtxPiReleasePreempt_Setup_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiReleasePreempt_Setup( ctx ); } /** * @brief Release the mutex. */ static void RtemsSemReqPerfMtxPiReleasePreempt_Body( RtemsSemValPerf_Context *ctx ) { ctx->begin = T_tick(); ctx->status = rtems_semaphore_release( ctx->mutex_id ); } static void RtemsSemReqPerfMtxPiReleasePreempt_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiReleasePreempt_Body( ctx ); } /** * @brief Set the measured runtime. Discard samples interrupted by a clock * tick. */ static bool RtemsSemReqPerfMtxPiReleasePreempt_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc( ctx->status, RTEMS_SUCCESSFUL ); *delta = ctx->end - ctx->begin; return tic == toc; } static bool RtemsSemReqPerfMtxPiReleasePreempt_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiReleasePreempt_Teardown( ctx, delta, tic, toc, retry ); } /** @} */ /** * @defgroup RtemsSemReqPerfMtxPiTry spec:/rtems/sem/req/perf-mtx-pi-try * * @{ */ /** * @brief Make the mutex unavailable. */ static void RtemsSemReqPerfMtxPiTry_Prepare( RtemsSemValPerf_Context *ctx ) { Send( ctx, EVENT_OBTAIN ); } /** * @brief Try to obtain the unavailable mutex. */ static void RtemsSemReqPerfMtxPiTry_Body( RtemsSemValPerf_Context *ctx ) { ctx->status = rtems_semaphore_obtain( ctx->mutex_id, RTEMS_NO_WAIT, 0 ); } static void RtemsSemReqPerfMtxPiTry_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiTry_Body( ctx ); } /** * @brief Discard samples interrupted by a clock tick. */ static bool RtemsSemReqPerfMtxPiTry_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc( ctx->status, RTEMS_UNSATISFIED ); return tic == toc; } static bool RtemsSemReqPerfMtxPiTry_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiTry_Teardown( ctx, delta, tic, toc, retry ); } /** * @brief Make the mutex available. */ static void RtemsSemReqPerfMtxPiTry_Cleanup( RtemsSemValPerf_Context *ctx ) { Send( ctx, EVENT_RELEASE ); } /** @} */ /** * @defgroup RtemsSemReqPerfMtxPiWaitForever \ * spec:/rtems/sem/req/perf-mtx-pi-wait-forever * * @{ */ /** * @brief Make the mutex unavailable. */ static void RtemsSemReqPerfMtxPiWaitForever_Setup( RtemsSemValPerf_Context *ctx ) { Send( ctx, EVENT_OBTAIN ); SetSelfPriority( PRIO_VERY_HIGH ); Send( ctx, EVENT_END | EVENT_RELEASE ); } static void RtemsSemReqPerfMtxPiWaitForever_Setup_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiWaitForever_Setup( ctx ); } /** * @brief Obtain the unavailable mutex and wait forever. */ static void RtemsSemReqPerfMtxPiWaitForever_Body( RtemsSemValPerf_Context *ctx ) { ctx->begin = T_tick(); ctx->status = rtems_semaphore_obtain( ctx->mutex_id, RTEMS_WAIT, RTEMS_NO_TIMEOUT ); } static void RtemsSemReqPerfMtxPiWaitForever_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiWaitForever_Body( ctx ); } /** * @brief Set the measured runtime. Restore the worker priority. Release the * mutex. Discard samples interrupted by a clock tick. */ static bool RtemsSemReqPerfMtxPiWaitForever_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc( ctx->status, RTEMS_SUCCESSFUL ); *delta = ctx->end - ctx->begin; ReleaseMutex( ctx->mutex_id ); SetSelfPriority( PRIO_NORMAL ); return tic == toc; } static bool RtemsSemReqPerfMtxPiWaitForever_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiWaitForever_Teardown( ctx, delta, tic, toc, retry ); } /** @} */ /** * @defgroup RtemsSemReqPerfMtxPiWaitTimed \ * spec:/rtems/sem/req/perf-mtx-pi-wait-timed * * @{ */ /** * @brief Make the mutex unavailable. */ static void RtemsSemReqPerfMtxPiWaitTimed_Setup( RtemsSemValPerf_Context *ctx ) { Send( ctx, EVENT_OBTAIN ); SetSelfPriority( PRIO_VERY_HIGH ); Send( ctx, EVENT_END | EVENT_RELEASE ); } static void RtemsSemReqPerfMtxPiWaitTimed_Setup_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiWaitTimed_Setup( ctx ); } /** * @brief Obtain the unavailable mutex and wait forever. */ static void RtemsSemReqPerfMtxPiWaitTimed_Body( RtemsSemValPerf_Context *ctx ) { ctx->begin = T_tick(); ctx->status = rtems_semaphore_obtain( ctx->mutex_id, RTEMS_WAIT, UINT32_MAX ); } static void RtemsSemReqPerfMtxPiWaitTimed_Body_Wrap( void *arg ) { RtemsSemValPerf_Context *ctx; ctx = arg; RtemsSemReqPerfMtxPiWaitTimed_Body( ctx ); } /** * @brief Set the measured runtime. Restore the worker priority. Release the * mutex. Discard samples interrupted by a clock tick. */ static bool RtemsSemReqPerfMtxPiWaitTimed_Teardown( RtemsSemValPerf_Context *ctx, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { T_quiet_rsc( ctx->status, RTEMS_SUCCESSFUL ); *delta = ctx->end - ctx->begin; ReleaseMutex( ctx->mutex_id ); SetSelfPriority( PRIO_NORMAL ); return tic == toc; } static bool RtemsSemReqPerfMtxPiWaitTimed_Teardown_Wrap( void *arg, T_ticks *delta, uint32_t tic, uint32_t toc, unsigned int retry ) { RtemsSemValPerf_Context *ctx; ctx = arg; return RtemsSemReqPerfMtxPiWaitTimed_Teardown( ctx, delta, tic, toc, retry ); } /** @} */ /** * @fn void T_case_body_RtemsSemValPerf( void ) */ T_TEST_CASE_FIXTURE( RtemsSemValPerf, &RtemsSemValPerf_Fixture ) { RtemsSemValPerf_Context *ctx; ctx = T_fixture_context(); ctx->request.name = "RtemsSemReqPerfMtxPiObtain"; ctx->request.setup = NULL; ctx->request.body = RtemsSemReqPerfMtxPiObtain_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiObtain_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); ctx->request.name = "RtemsSemReqPerfMtxPiRelease"; ctx->request.setup = RtemsSemReqPerfMtxPiRelease_Setup_Wrap; ctx->request.body = RtemsSemReqPerfMtxPiRelease_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiRelease_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); ctx->request.name = "RtemsSemReqPerfMtxPiReleaseOne"; ctx->request.setup = RtemsSemReqPerfMtxPiReleaseOne_Setup_Wrap; ctx->request.body = RtemsSemReqPerfMtxPiReleaseOne_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiReleaseOne_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); #if defined(RTEMS_SMP) RtemsSemReqPerfMtxPiReleaseOtherCpu_Prepare( ctx ); ctx->request.name = "RtemsSemReqPerfMtxPiReleaseOtherCpu"; ctx->request.setup = RtemsSemReqPerfMtxPiReleaseOtherCpu_Setup_Wrap; ctx->request.body = RtemsSemReqPerfMtxPiReleaseOtherCpu_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiReleaseOtherCpu_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); RtemsSemReqPerfMtxPiReleaseOtherCpu_Cleanup( ctx ); #endif ctx->request.name = "RtemsSemReqPerfMtxPiReleasePreempt"; ctx->request.setup = RtemsSemReqPerfMtxPiReleasePreempt_Setup_Wrap; ctx->request.body = RtemsSemReqPerfMtxPiReleasePreempt_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiReleasePreempt_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); RtemsSemReqPerfMtxPiTry_Prepare( ctx ); ctx->request.name = "RtemsSemReqPerfMtxPiTry"; ctx->request.setup = NULL; ctx->request.body = RtemsSemReqPerfMtxPiTry_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiTry_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); RtemsSemReqPerfMtxPiTry_Cleanup( ctx ); ctx->request.name = "RtemsSemReqPerfMtxPiWaitForever"; ctx->request.setup = RtemsSemReqPerfMtxPiWaitForever_Setup_Wrap; ctx->request.body = RtemsSemReqPerfMtxPiWaitForever_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiWaitForever_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); ctx->request.name = "RtemsSemReqPerfMtxPiWaitTimed"; ctx->request.setup = RtemsSemReqPerfMtxPiWaitTimed_Setup_Wrap; ctx->request.body = RtemsSemReqPerfMtxPiWaitTimed_Body_Wrap; ctx->request.teardown = RtemsSemReqPerfMtxPiWaitTimed_Teardown_Wrap; T_measure_runtime( ctx->context, &ctx->request ); } /** @} */