/* $Id: tstRTR0Timer.cpp 62477 2016-07-22 18:27:37Z vboxsync $ */ /** @file * IPRT R0 Testcase - Timers. */ /* * Copyright (C) 2009-2016 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include "tstRTR0Timer.h" #include "tstRTR0Common.h" /********************************************************************************************************************************* * Structures and Typedefs * *********************************************************************************************************************************/ typedef struct { /** Array of nano second timestamp of the first few shots. */ uint64_t volatile aShotNsTSes[10]; /** The number of shots. */ uint32_t volatile cShots; /** The shot at which action is to be taken. */ uint32_t iActionShot; /** The RC of whatever operation performed in the handler. */ int volatile rc; /** Set if it's a periodic test. */ bool fPeriodic; /** Test specific stuff. */ union { /** tstRTR0TimerCallbackU32ChangeInterval parameters. */ struct { /** The interval change step. */ uint32_t cNsChangeStep; /** The current timer interval. */ uint32_t cNsCurInterval; /** The minimum interval. */ uint32_t cNsMinInterval; /** The maximum interval. */ uint32_t cNsMaxInterval; /** Direction flag; false = decrement, true = increment. */ bool fDirection; /** The number of steps between each change. */ uint8_t cStepsBetween; } ChgInt; /** tstRTR0TimerCallbackSpecific parameters. */ struct { /** The expected CPU. */ RTCPUID idCpu; /** Set if this failed. */ bool fFailed; } Specific; } u; } TSTRTR0TIMERS1; typedef TSTRTR0TIMERS1 *PTSTRTR0TIMERS1; /** * Per cpu state for an omni timer test. */ typedef struct TSTRTR0TIMEROMNI1 { /** When we started receiving timer callbacks on this CPU. */ uint64_t u64Start; /** When we received the last tick on this timer. */ uint64_t u64Last; /** The number of ticks received on this CPU. */ uint32_t volatile cTicks; uint32_t u32Padding; } TSTRTR0TIMEROMNI1; typedef TSTRTR0TIMEROMNI1 *PTSTRTR0TIMEROMNI1; /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** * Latency data. */ static struct TSTRTR0TIMEROMNILATENCY { /** The number of samples. */ volatile uint32_t cSamples; uint32_t auPadding[3]; struct { uint64_t uTsc; uint64_t uNanoTs; } aSamples[4096]; } g_aOmniLatency[16]; /** * Callback for the omni timer latency test, adds a sample to g_aOmniLatency. * * @param pTimer The timer. * @param iTick The current tick. * @param pvUser The user argument. */ static DECLCALLBACK(void) tstRTR0TimerCallbackLatencyOmni(PRTTIMER pTimer, void *pvUser, uint64_t iTick) { RTCPUID idCpu = RTMpCpuId(); uint32_t iCpu = RTMpCpuIdToSetIndex(idCpu); NOREF(pTimer); NOREF(pvUser); NOREF(iTick); RTR0TESTR0_CHECK_MSG(iCpu < RT_ELEMENTS(g_aOmniLatency), ("iCpu=%d idCpu=%u\n", iCpu, idCpu)); if (iCpu < RT_ELEMENTS(g_aOmniLatency)) { uint32_t iSample = g_aOmniLatency[iCpu].cSamples; if (iSample < RT_ELEMENTS(g_aOmniLatency[iCpu].aSamples)) { g_aOmniLatency[iCpu].aSamples[iSample].uTsc = ASMReadTSC(); g_aOmniLatency[iCpu].aSamples[iSample].uNanoTs = RTTimeSystemNanoTS(); g_aOmniLatency[iCpu].cSamples = iSample + 1; } } } /** * Callback which increments a 32-bit counter. * * @param pTimer The timer. * @param iTick The current tick. * @param pvUser The user argument. */ static DECLCALLBACK(void) tstRTR0TimerCallbackOmni(PRTTIMER pTimer, void *pvUser, uint64_t iTick) { PTSTRTR0TIMEROMNI1 paStates = (PTSTRTR0TIMEROMNI1)pvUser; RTCPUID idCpu = RTMpCpuId(); uint32_t iCpu = RTMpCpuIdToSetIndex(idCpu); NOREF(pTimer); RTR0TESTR0_CHECK_MSG(iCpu < RTCPUSET_MAX_CPUS, ("iCpu=%d idCpu=%u\n", iCpu, idCpu)); if (iCpu < RTCPUSET_MAX_CPUS) { uint32_t iCountedTick = ASMAtomicIncU32(&paStates[iCpu].cTicks); RTR0TESTR0_CHECK_MSG(iCountedTick == iTick, ("iCountedTick=%u iTick=%u iCpu=%d idCpu=%u\n", iCountedTick, iTick, iCpu, idCpu)); paStates[iCpu].u64Last = RTTimeSystemNanoTS(); if (!paStates[iCpu].u64Start) { paStates[iCpu].u64Start = paStates[iCpu].u64Last; RTR0TESTR0_CHECK_MSG(iCountedTick == 1, ("iCountedTick=%u iCpu=%d idCpu=%u\n", iCountedTick, iCpu, idCpu)); } } } /** * Callback which increments a 32-bit counter. * * @param pTimer The timer. * @param iTick The current tick. * @param pvUser The user argument. */ static DECLCALLBACK(void) tstRTR0TimerCallbackSpecific(PRTTIMER pTimer, void *pvUser, uint64_t iTick) { PTSTRTR0TIMERS1 pState = (PTSTRTR0TIMERS1)pvUser; uint32_t iShot = ASMAtomicIncU32(&pState->cShots); NOREF(pTimer); if (iShot <= RT_ELEMENTS(pState->aShotNsTSes)) pState->aShotNsTSes[iShot - 1] = RTTimeSystemNanoTS(); RTCPUID idCpu = RTMpCpuId(); if (pState->u.Specific.idCpu != idCpu) pState->u.Specific.fFailed = true; RTR0TESTR0_CHECK_MSG(pState->u.Specific.idCpu == idCpu, ("idCpu=%u, expected %u\n", idCpu, pState->u.Specific.idCpu)); if (pState->fPeriodic) RTR0TESTR0_CHECK_MSG(iShot == iTick, ("iShot=%u iTick=%u\n", iShot, iTick)); else RTR0TESTR0_CHECK_MSG(iTick == 1, ("iShot=%u iTick=%u\n", iShot, iTick)); } /** * Callback which changes the interval at each invocation. * * The changes are governed by TSTRTR0TIMERS1::ChangeInterval. The callback * calls RTTimerStop at iActionShot. * * @param pTimer The timer. * @param iTick The current tick. * @param pvUser The user argument. */ static DECLCALLBACK(void) tstRTR0TimerCallbackChangeInterval(PRTTIMER pTimer, void *pvUser, uint64_t iTick) { PTSTRTR0TIMERS1 pState = (PTSTRTR0TIMERS1)pvUser; uint32_t iShot = ASMAtomicIncU32(&pState->cShots) - 1; if (iShot < RT_ELEMENTS(pState->aShotNsTSes)) pState->aShotNsTSes[iShot] = RTTimeSystemNanoTS(); if (pState->fPeriodic) RTR0TESTR0_CHECK_MSG(iShot + 1 == iTick, ("iShot=%u iTick=%u\n", iShot, iTick)); else RTR0TESTR0_CHECK_MSG(iTick == 1, ("iShot=%u iTick=%u\n", iShot, iTick)); if (!(iShot % pState->u.ChgInt.cStepsBetween)) { if (pState->u.ChgInt.fDirection) { pState->u.ChgInt.cNsCurInterval += pState->u.ChgInt.cNsChangeStep; if ( pState->u.ChgInt.cNsCurInterval > pState->u.ChgInt.cNsMaxInterval || pState->u.ChgInt.cNsCurInterval < pState->u.ChgInt.cNsMinInterval || !pState->u.ChgInt.cNsCurInterval) { pState->u.ChgInt.cNsCurInterval = pState->u.ChgInt.cNsMaxInterval; pState->u.ChgInt.fDirection = false; } } else { pState->u.ChgInt.cNsCurInterval -= pState->u.ChgInt.cNsChangeStep; if ( pState->u.ChgInt.cNsCurInterval < pState->u.ChgInt.cNsMinInterval || pState->u.ChgInt.cNsCurInterval > pState->u.ChgInt.cNsMaxInterval || pState->u.ChgInt.cNsCurInterval) { pState->u.ChgInt.cNsCurInterval = pState->u.ChgInt.cNsMinInterval; pState->u.ChgInt.fDirection = true; } } RTR0TESTR0_CHECK_RC(RTTimerChangeInterval(pTimer, pState->u.ChgInt.cNsCurInterval), VINF_SUCCESS); } if (iShot == pState->iActionShot) RTR0TESTR0_CHECK_RC(pState->rc = RTTimerStop(pTimer), VINF_SUCCESS); } /** * Callback which increments destroy the timer when it fires. * * @param pTimer The timer. * @param iTick The current tick. * @param pvUser The user argument. */ static DECLCALLBACK(void) tstRTR0TimerCallbackDestroyOnce(PRTTIMER pTimer, void *pvUser, uint64_t iTick) { PTSTRTR0TIMERS1 pState = (PTSTRTR0TIMERS1)pvUser; uint32_t iShot = ASMAtomicIncU32(&pState->cShots); if (iShot <= RT_ELEMENTS(pState->aShotNsTSes)) pState->aShotNsTSes[iShot - 1] = RTTimeSystemNanoTS(); if (pState->fPeriodic) RTR0TESTR0_CHECK_MSG(iShot == iTick, ("iShot=%u iTick=%u\n", iShot, iTick)); else RTR0TESTR0_CHECK_MSG(iTick == 1, ("iShot=%u iTick=%u\n", iShot, iTick)); if (iShot == pState->iActionShot + 1) RTR0TESTR0_CHECK_RC(pState->rc = RTTimerDestroy(pTimer), VINF_SUCCESS); } /** * Callback which increments restarts a timer once. * * @param pTimer The timer. * @param iTick The current tick. * @param pvUser The user argument. */ static DECLCALLBACK(void) tstRTR0TimerCallbackRestartOnce(PRTTIMER pTimer, void *pvUser, uint64_t iTick) { PTSTRTR0TIMERS1 pState = (PTSTRTR0TIMERS1)pvUser; uint32_t iShot = ASMAtomicIncU32(&pState->cShots); if (iShot <= RT_ELEMENTS(pState->aShotNsTSes)) pState->aShotNsTSes[iShot - 1] = RTTimeSystemNanoTS(); if (pState->fPeriodic) RTR0TESTR0_CHECK_MSG(iShot == iTick, ("iShot=%u iTick=%u\n", iShot, iTick)); else RTR0TESTR0_CHECK_MSG(iTick == 1, ("iShot=%u iTick=%u\n", iShot, iTick)); if (iShot == pState->iActionShot + 1) RTR0TESTR0_CHECK_RC(pState->rc = RTTimerStart(pTimer, 10000000 /* 10ms */), VINF_SUCCESS); } /** * Callback which increments a 32-bit counter. * * @param pTimer The timer. * @param iTick The current tick. * @param pvUser The user argument. */ static DECLCALLBACK(void) tstRTR0TimerCallbackU32Counter(PRTTIMER pTimer, void *pvUser, uint64_t iTick) { PTSTRTR0TIMERS1 pState = (PTSTRTR0TIMERS1)pvUser; uint32_t iShot = ASMAtomicIncU32(&pState->cShots); NOREF(pTimer); if (iShot <= RT_ELEMENTS(pState->aShotNsTSes)) pState->aShotNsTSes[iShot - 1] = RTTimeSystemNanoTS(); if (pState->fPeriodic) RTR0TESTR0_CHECK_MSG(iShot == iTick, ("iShot=%u iTick=%u\n", iShot, iTick)); else RTR0TESTR0_CHECK_MSG(iTick == 1, ("iShot=%u iTick=%u\n", iShot, iTick)); } #ifdef SOME_UNUSED_FUNCTION /** * Checks that the interval between two timer shots are within the specified * range. * * @returns 0 if ok, 1 if bad. * @param iShot The shot number (for bitching). * @param uPrevTS The time stamp of the previous shot (ns). * @param uThisTS The timer stamp of this shot (ns). * @param uMin The minimum interval (ns). * @param uMax The maximum interval (ns). */ static int tstRTR0TimerCheckShotInterval(uint32_t iShot, uint64_t uPrevTS, uint64_t uThisTS, uint32_t uMin, uint32_t uMax) { uint64_t uDelta = uThisTS - uPrevTS; RTR0TESTR0_CHECK_MSG_RET(uDelta >= uMin, ("iShot=%u uDelta=%lld uMin=%u\n", iShot, uDelta, uMin), 1); RTR0TESTR0_CHECK_MSG_RET(uDelta <= uMax, ("iShot=%u uDelta=%lld uMax=%u\n", iShot, uDelta, uMax), 1); return 0; } #endif /** * Checks that the interval between timer shots are within a certain range. * * @returns Number of violations (i.e. 0 is ok). * @param pState The state. * @param uStartNsTS The start time stamp (ns). * @param uMin The minimum interval (ns). * @param uMax The maximum interval (ns). */ static int tstRTR0TimerCheckShotIntervals(PTSTRTR0TIMERS1 pState, uint64_t uStartNsTS, uint32_t uMin, uint32_t uMax) { uint64_t uMaxDelta = 0; uint64_t uMinDelta = UINT64_MAX; uint32_t cBadShots = 0; uint32_t cShots = pState->cShots; uint64_t uPrevTS = uStartNsTS; for (uint32_t iShot = 0; iShot < cShots; iShot++) { uint64_t uThisTS = pState->aShotNsTSes[iShot]; uint64_t uDelta = uThisTS - uPrevTS; if (uDelta > uMaxDelta) uMaxDelta = uDelta; if (uDelta < uMinDelta) uMinDelta = uDelta; cBadShots += !(uDelta >= uMin && uDelta <= uMax); RTR0TESTR0_CHECK_MSG(uDelta >= uMin, ("iShot=%u uDelta=%lld uMin=%u\n", iShot, uDelta, uMin)); RTR0TESTR0_CHECK_MSG(uDelta <= uMax, ("iShot=%u uDelta=%lld uMax=%u\n", iShot, uDelta, uMax)); uPrevTS = uThisTS; } RTR0TestR0Info("uMaxDelta=%llu uMinDelta=%llu\n", uMaxDelta, uMinDelta); return cBadShots; } /** * Service request callback function. * * @returns VBox status code. * @param pSession The caller's session. * @param u64Arg 64-bit integer argument. * @param pReqHdr The request header. Input / Output. Optional. */ DECLEXPORT(int) TSTRTR0TimerSrvReqHandler(PSUPDRVSESSION pSession, uint32_t uOperation, uint64_t u64Arg, PSUPR0SERVICEREQHDR pReqHdr) { RTR0TESTR0_SRV_REQ_PROLOG_RET(pReqHdr); NOREF(pSession); /* * Common parameter and state variables. */ uint32_t const cNsSysHz = RTTimerGetSystemGranularity(); uint32_t const cNsMaxHighResHz = 10000; /** @todo need API for this */ TSTRTR0TIMERS1 State; if ( cNsSysHz < UINT32_C(1000) || cNsSysHz > UINT32_C(1000000000) || cNsMaxHighResHz < UINT32_C(1) || cNsMaxHighResHz > UINT32_C(1000000000)) { RTR0TESTR0_CHECK_MSG(cNsSysHz > UINT32_C(1000) && cNsSysHz < UINT32_C(1000000000), ("%u", cNsSysHz)); RTR0TESTR0_CHECK_MSG(cNsMaxHighResHz > UINT32_C(1) && cNsMaxHighResHz < UINT32_C(1000000000), ("%u", cNsMaxHighResHz)); RTR0TESTR0_SRV_REQ_EPILOG(pReqHdr); return VINF_SUCCESS; } /* * The big switch. */ switch (uOperation) { RTR0TESTR0_IMPLEMENT_SANITY_CASES(); RTR0TESTR0_IMPLEMENT_DEFAULT_CASE(uOperation); case TSTRTR0TIMER_ONE_SHOT_BASIC: case TSTRTR0TIMER_ONE_SHOT_BASIC_HIRES: { /* Create a one-shot timer and take one shot. */ PRTTIMER pTimer; uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; int rc = RTTimerCreateEx(&pTimer, 0, fFlags, tstRTR0TimerCallbackU32Counter, &State); if (rc == VERR_NOT_SUPPORTED) { RTR0TestR0Info("one-shot timer are not supported, skipping\n"); RTR0TESTR0_SKIP(); break; } RTR0TESTR0_CHECK_RC_BREAK(rc, VINF_SUCCESS); do /* break loop */ { RT_ZERO(State); ASMAtomicWriteU32(&State.cShots, State.cShots); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, 0), VINF_SUCCESS); for (uint32_t i = 0; i < 1000 && !ASMAtomicUoReadU32(&State.cShots); i++) RTThreadSleep(5); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicUoReadU32(&State.cShots) == 1, ("cShots=%u\n", State.cShots)); /* check that it is restartable. */ RT_ZERO(State); ASMAtomicWriteU32(&State.cShots, State.cShots); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, 0), VINF_SUCCESS); for (uint32_t i = 0; i < 1000 && !ASMAtomicUoReadU32(&State.cShots); i++) RTThreadSleep(5); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicUoReadU32(&State.cShots) == 1, ("cShots=%u\n", State.cShots)); /* check that it respects the timeout value and can be cancelled. */ RT_ZERO(State); ASMAtomicWriteU32(&State.cShots, State.cShots); RTR0TESTR0_CHECK_RC(RTTimerStart(pTimer, 5*UINT64_C(1000000000)), VINF_SUCCESS); RTR0TESTR0_CHECK_RC(RTTimerStop(pTimer), VINF_SUCCESS); RTThreadSleep(1); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicUoReadU32(&State.cShots) == 0, ("cShots=%u\n", State.cShots)); /* Check some double starts and stops (shall not assert). */ RT_ZERO(State); ASMAtomicWriteU32(&State.cShots, State.cShots); RTR0TESTR0_CHECK_RC(RTTimerStart(pTimer, 5*UINT64_C(1000000000)), VINF_SUCCESS); RTR0TESTR0_CHECK_RC(RTTimerStart(pTimer, 0), VERR_TIMER_ACTIVE); RTR0TESTR0_CHECK_RC(RTTimerStop(pTimer), VINF_SUCCESS); RTR0TESTR0_CHECK_RC(RTTimerStop(pTimer), VERR_TIMER_SUSPENDED); RTThreadSleep(1); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicUoReadU32(&State.cShots) == 0, ("cShots=%u\n", State.cShots)); } while (0); RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); RTR0TESTR0_CHECK_RC(RTTimerDestroy(NULL), VINF_SUCCESS); break; } case TSTRTR0TIMER_ONE_SHOT_RESTART: case TSTRTR0TIMER_ONE_SHOT_RESTART_HIRES: { #if !defined(RT_OS_SOLARIS) /* Not expected to work on all hosts. */ /* Create a one-shot timer and restart it in the callback handler. */ PRTTIMER pTimer; uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; for (uint32_t iTest = 0; iTest < 2; iTest++) { int rc = RTTimerCreateEx(&pTimer, 0, fFlags, tstRTR0TimerCallbackRestartOnce, &State); if (rc == VERR_NOT_SUPPORTED) { RTR0TestR0Info("one-shot timer are not supported, skipping\n"); RTR0TESTR0_SKIP(); break; } RTR0TESTR0_CHECK_RC_BREAK(rc, VINF_SUCCESS); RT_ZERO(State); State.iActionShot = 0; ASMAtomicWriteU32(&State.cShots, State.cShots); do /* break loop */ { RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, cNsSysHz * iTest), VINF_SUCCESS); for (uint32_t i = 0; i < 1000 && ASMAtomicUoReadU32(&State.cShots) < 2; i++) RTThreadSleep(5); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicUoReadU32(&State.cShots) == 2, ("cShots=%u\n", State.cShots)); } while (0); RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); } #else RTR0TestR0Info("restarting from callback not supported on this platform\n"); RTR0TESTR0_SKIP(); #endif break; } case TSTRTR0TIMER_ONE_SHOT_DESTROY: case TSTRTR0TIMER_ONE_SHOT_DESTROY_HIRES: { #if !defined(RT_OS_SOLARIS) && !defined(RT_OS_WINDOWS) /* Not expected to work on all hosts. */ /* Create a one-shot timer and destroy it in the callback handler. */ PRTTIMER pTimer; uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; for (uint32_t iTest = 0; iTest < 2; iTest++) { int rc = RTTimerCreateEx(&pTimer, 0, fFlags, tstRTR0TimerCallbackDestroyOnce, &State); if (rc == VERR_NOT_SUPPORTED) { RTR0TestR0Info("one-shot timer are not supported, skipping\n"); RTR0TESTR0_SKIP(); break; } RTR0TESTR0_CHECK_RC_BREAK(rc, VINF_SUCCESS); RT_ZERO(State); State.rc = VERR_IPE_UNINITIALIZED_STATUS; State.iActionShot = 0; ASMAtomicWriteU32(&State.cShots, State.cShots); do /* break loop */ { RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, cNsSysHz * iTest), VINF_SUCCESS); for (uint32_t i = 0; i < 1000 && (ASMAtomicUoReadU32(&State.cShots) < 1 || State.rc == VERR_IPE_UNINITIALIZED_STATUS); i++) RTThreadSleep(5); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicReadU32(&State.cShots) == 1, ("cShots=%u\n", State.cShots)); RTR0TESTR0_CHECK_MSG_BREAK(State.rc == VINF_SUCCESS, ("rc=%Rrc\n", State.rc)); } while (0); if (RT_FAILURE(State.rc)) RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); } #else RTR0TestR0Info("destroying from callback not supported on this platform\n"); RTR0TESTR0_SKIP(); #endif break; } case TSTRTR0TIMER_ONE_SHOT_SPECIFIC: case TSTRTR0TIMER_ONE_SHOT_SPECIFIC_HIRES: { PRTTIMER pTimer = NULL; RTCPUSET OnlineSet; RTMpGetOnlineSet(&OnlineSet); for (uint32_t iCpu = 0; iCpu < RTCPUSET_MAX_CPUS; iCpu++) if (RTCpuSetIsMemberByIndex(&OnlineSet, iCpu)) { RT_ZERO(State); State.iActionShot = 0; State.rc = VINF_SUCCESS; State.u.Specific.idCpu = RTMpCpuIdFromSetIndex(iCpu); ASMAtomicWriteU32(&State.cShots, State.cShots); uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; fFlags |= RTTIMER_FLAGS_CPU(iCpu); int rc = RTTimerCreateEx(&pTimer, 0, fFlags, tstRTR0TimerCallbackSpecific, &State); if (rc == VERR_NOT_SUPPORTED) { RTR0TestR0Info("one-shot specific timer are not supported, skipping\n"); RTR0TESTR0_SKIP(); break; } RTR0TESTR0_CHECK_RC_BREAK(rc, VINF_SUCCESS); for (uint32_t i = 0; i < 5 && !RTR0TestR0HaveErrors(); i++) { ASMAtomicWriteU32(&State.cShots, 0); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, (i & 2 ? cNsSysHz : cNsSysHz / 2) * (i & 1)), VINF_SUCCESS); uint64_t cNsElapsed = RTTimeSystemNanoTS(); for (uint32_t j = 0; j < 1000 && ASMAtomicUoReadU32(&State.cShots) < 1; j++) RTThreadSleep(5); cNsElapsed = RTTimeSystemNanoTS() - cNsElapsed; RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicReadU32(&State.cShots) == 1, ("cShots=%u iCpu=%u i=%u iCurCpu=%u cNsElapsed=%'llu\n", State.cShots, iCpu, i, RTMpCpuIdToSetIndex(RTMpCpuId()), cNsElapsed )); RTR0TESTR0_CHECK_MSG_BREAK(State.rc == VINF_SUCCESS, ("rc=%Rrc\n", State.rc)); RTR0TESTR0_CHECK_MSG_BREAK(!State.u.Specific.fFailed, ("iCpu=%u i=%u\n", iCpu, i)); } RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); pTimer = NULL; if (RTR0TestR0HaveErrors()) break; RTMpGetOnlineSet(&OnlineSet); } RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); break; } case TSTRTR0TIMER_PERIODIC_BASIC: case TSTRTR0TIMER_PERIODIC_BASIC_HIRES: { /* Create a periodic timer running at 10 HZ. */ uint32_t const u10HzAsNs = 100000000; uint32_t const u10HzAsNsMin = u10HzAsNs - u10HzAsNs / 2; uint32_t const u10HzAsNsMax = u10HzAsNs + u10HzAsNs / 2; PRTTIMER pTimer; uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; RTR0TESTR0_CHECK_RC_BREAK(RTTimerCreateEx(&pTimer, u10HzAsNs, fFlags, tstRTR0TimerCallbackU32Counter, &State), VINF_SUCCESS); for (uint32_t iTest = 0; iTest < 2; iTest++) { RT_ZERO(State); State.fPeriodic = true; ASMAtomicWriteU32(&State.cShots, State.cShots); uint64_t uStartNsTS = RTTimeSystemNanoTS(); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, u10HzAsNs), VINF_SUCCESS); for (uint32_t i = 0; i < 1000 && ASMAtomicUoReadU32(&State.cShots) < 10; i++) RTThreadSleep(10); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStop(pTimer), VINF_SUCCESS); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicUoReadU32(&State.cShots) == 10, ("cShots=%u\n", State.cShots)); if (tstRTR0TimerCheckShotIntervals(&State, uStartNsTS, u10HzAsNsMin, u10HzAsNsMax)) break; RTThreadSleep(1); /** @todo RTTimerStop doesn't currently make sure the timer callback not is running * before returning on windows, linux (low res) and possible other plaforms. */ } RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); RTR0TESTR0_CHECK_RC(RTTimerDestroy(NULL), VINF_SUCCESS); break; } case TSTRTR0TIMER_PERIODIC_CSSD_LOOPS: case TSTRTR0TIMER_PERIODIC_CSSD_LOOPS_HIRES: { /* create, start, stop & destroy high res timers a number of times. */ uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; for (uint32_t i = 0; i < 40; i++) { PRTTIMER pTimer; RTR0TESTR0_CHECK_RC_BREAK(RTTimerCreateEx(&pTimer, cNsSysHz, fFlags, tstRTR0TimerCallbackU32Counter, &State), VINF_SUCCESS); for (uint32_t j = 0; j < 10; j++) { RT_ZERO(State); State.fPeriodic = true; ASMAtomicWriteU32(&State.cShots, State.cShots); /* ordered, necessary? */ RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, i < 20 ? 0 : cNsSysHz), VINF_SUCCESS); for (uint32_t k = 0; k < 1000 && ASMAtomicUoReadU32(&State.cShots) < 2; k++) RTThreadSleep(1); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStop(pTimer), VINF_SUCCESS); RTThreadSleep(1); /** @todo RTTimerStop doesn't currently make sure the timer callback not is running * before returning on windows, linux (low res) and possible other plaforms. */ } RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); } break; } case TSTRTR0TIMER_PERIODIC_CHANGE_INTERVAL: case TSTRTR0TIMER_PERIODIC_CHANGE_INTERVAL_HIRES: { /* Initialize the test parameters, using the u64Arg value for selecting variations. */ RT_ZERO(State); State.cShots = 0; State.rc = VERR_IPE_UNINITIALIZED_STATUS; State.iActionShot = 42; State.fPeriodic = true; State.u.ChgInt.fDirection = !!(u64Arg & 1); if (uOperation == TSTRTR0TIMER_PERIODIC_CHANGE_INTERVAL_HIRES) { State.u.ChgInt.cNsMaxInterval = RT_MAX(cNsMaxHighResHz * 10, 20000000); /* 10x / 20 ms */ State.u.ChgInt.cNsMinInterval = RT_MAX(cNsMaxHighResHz, 10000); /* min / 10 us */ } else { State.u.ChgInt.cNsMaxInterval = cNsSysHz * 4; State.u.ChgInt.cNsMinInterval = cNsSysHz; } State.u.ChgInt.cNsChangeStep = (State.u.ChgInt.cNsMaxInterval - State.u.ChgInt.cNsMinInterval) / 10; State.u.ChgInt.cNsCurInterval = State.u.ChgInt.fDirection ? State.u.ChgInt.cNsMaxInterval : State.u.ChgInt.cNsMinInterval; State.u.ChgInt.cStepsBetween = u64Arg & 4 ? 1 : 3; RTR0TESTR0_CHECK_MSG_BREAK(State.u.ChgInt.cNsMinInterval > 1000, ("%u\n", State.u.ChgInt.cNsMinInterval)); RTR0TESTR0_CHECK_MSG_BREAK(State.u.ChgInt.cNsMaxInterval > State.u.ChgInt.cNsMinInterval, ("max=%u min=%u\n", State.u.ChgInt.cNsMaxInterval, State.u.ChgInt.cNsMinInterval)); ASMAtomicWriteU32(&State.cShots, State.cShots); /* create the timer and check if RTTimerChangeInterval is supported. */ PRTTIMER pTimer; uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; RTR0TESTR0_CHECK_RC_BREAK(RTTimerCreateEx(&pTimer, cNsSysHz, fFlags, tstRTR0TimerCallbackChangeInterval, &State), VINF_SUCCESS); int rc = RTTimerChangeInterval(pTimer, State.u.ChgInt.cNsMinInterval); if (rc == VERR_NOT_SUPPORTED) { RTR0TestR0Info("RTTimerChangeInterval not supported, skipped"); RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); RTR0TESTR0_SKIP(); break; } /* do the test. */ RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, u64Arg & 2 ? State.u.ChgInt.cNsCurInterval : 0), VINF_SUCCESS); for (uint32_t k = 0; k < 1000 && ASMAtomicReadU32(&State.cShots) <= State.iActionShot && State.rc == VERR_IPE_UNINITIALIZED_STATUS; k++) RTThreadSleep(10); rc = RTTimerStop(pTimer); RTR0TESTR0_CHECK_MSG_BREAK(rc == VERR_TIMER_SUSPENDED || rc == VINF_SUCCESS, ("rc = %Rrc (RTTimerStop)\n", rc)); RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); break; } case TSTRTR0TIMER_PERIODIC_SPECIFIC: case TSTRTR0TIMER_PERIODIC_SPECIFIC_HIRES: { PRTTIMER pTimer = NULL; RTCPUSET OnlineSet; RTMpGetOnlineSet(&OnlineSet); for (uint32_t iCpu = 0; iCpu < RTCPUSET_MAX_CPUS; iCpu++) if (RTCpuSetIsMemberByIndex(&OnlineSet, iCpu)) { RT_ZERO(State); State.iActionShot = 0; State.rc = VINF_SUCCESS; State.fPeriodic = true; State.u.Specific.idCpu = RTMpCpuIdFromSetIndex(iCpu); ASMAtomicWriteU32(&State.cShots, State.cShots); uint32_t fFlags = TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0; fFlags |= RTTIMER_FLAGS_CPU(iCpu); int rc = RTTimerCreateEx(&pTimer, cNsSysHz, fFlags, tstRTR0TimerCallbackSpecific, &State); if (rc == VERR_NOT_SUPPORTED) { RTR0TestR0Info("specific timer are not supported, skipping\n"); RTR0TESTR0_SKIP(); break; } RTR0TESTR0_CHECK_RC_BREAK(rc, VINF_SUCCESS); for (uint32_t i = 0; i < 3 && !RTR0TestR0HaveErrors(); i++) { ASMAtomicWriteU32(&State.cShots, 0); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, (i & 2 ? cNsSysHz : cNsSysHz / 2) * (i & 1)), VINF_SUCCESS); uint64_t cNsElapsed = RTTimeSystemNanoTS(); for (uint32_t j = 0; j < 1000 && ASMAtomicUoReadU32(&State.cShots) < 8; j++) RTThreadSleep(5); cNsElapsed = RTTimeSystemNanoTS() - cNsElapsed; RTR0TESTR0_CHECK_RC_BREAK(RTTimerStop(pTimer), VINF_SUCCESS); RTR0TESTR0_CHECK_MSG_BREAK(ASMAtomicReadU32(&State.cShots) > 5, ("cShots=%u iCpu=%u i=%u iCurCpu=%u cNsElapsed=%'llu\n", State.cShots, iCpu, i, RTMpCpuIdToSetIndex(RTMpCpuId()), cNsElapsed)); RTThreadSleep(1); /** @todo RTTimerStop doesn't currently make sure the timer callback not is running * before returning on windows, linux (low res) and possible other plaforms. */ RTR0TESTR0_CHECK_MSG_BREAK(State.rc == VINF_SUCCESS, ("rc=%Rrc\n", State.rc)); RTR0TESTR0_CHECK_MSG_BREAK(!State.u.Specific.fFailed, ("iCpu=%u i=%u\n", iCpu, i)); } RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); pTimer = NULL; if (RTR0TestR0HaveErrors()) break; RTMpGetOnlineSet(&OnlineSet); } RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); break; } case TSTRTR0TIMER_PERIODIC_OMNI: case TSTRTR0TIMER_PERIODIC_OMNI_HIRES: { /* Create a periodic timer running at max host frequency, but no more than 1000 Hz. */ uint32_t cNsInterval = cNsSysHz; while (cNsInterval < UINT32_C(1000000)) cNsInterval *= 2; PTSTRTR0TIMEROMNI1 paStates = (PTSTRTR0TIMEROMNI1)RTMemAllocZ(sizeof(paStates[0]) * RTCPUSET_MAX_CPUS); RTR0TESTR0_CHECK_MSG_BREAK(paStates, ("%d\n", RTCPUSET_MAX_CPUS)); PRTTIMER pTimer; uint32_t fFlags = (TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0) | RTTIMER_FLAGS_CPU_ALL; int rc = RTTimerCreateEx(&pTimer, cNsInterval, fFlags, tstRTR0TimerCallbackOmni, paStates); if (rc == VERR_NOT_SUPPORTED) { RTR0TESTR0_SKIP_BREAK(); } RTR0TESTR0_CHECK_RC_BREAK(rc, VINF_SUCCESS); for (uint32_t iTest = 0; iTest < 3 && !RTR0TestR0HaveErrors(); iTest++) { /* reset the state */ for (uint32_t iCpu = 0; iCpu < RTCPUSET_MAX_CPUS; iCpu++) { paStates[iCpu].u64Start = 0; paStates[iCpu].u64Last = 0; ASMAtomicWriteU32(&paStates[iCpu].cTicks, 0); } /* run it for 1 second. */ RTCPUSET OnlineSet; uint64_t uStartNsTS = RTTimeSystemNanoTS(); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, 0), VINF_SUCCESS); RTMpGetOnlineSet(&OnlineSet); for (uint32_t i = 0; i < 5000 && RTTimeSystemNanoTS() - uStartNsTS <= UINT32_C(1000000000); i++) RTThreadSleep(2); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStop(pTimer), VINF_SUCCESS); uint64_t cNsElapsedX = RTTimeNanoTS() - uStartNsTS; /* Do a min/max on the start and stop times and calculate the test period. */ uint64_t u64MinStart = UINT64_MAX; uint64_t u64MaxStop = 0; for (uint32_t iCpu = 0; iCpu < RTCPUSET_MAX_CPUS; iCpu++) { if (paStates[iCpu].u64Start) { if (paStates[iCpu].u64Start < u64MinStart) u64MinStart = paStates[iCpu].u64Start; if (paStates[iCpu].u64Last > u64MaxStop) u64MaxStop = paStates[iCpu].u64Last; } } RTR0TESTR0_CHECK_MSG(u64MinStart < u64MaxStop, ("%llu, %llu", u64MinStart, u64MaxStop)); uint64_t cNsElapsed = u64MaxStop - u64MinStart; RTR0TESTR0_CHECK_MSG(cNsElapsed <= cNsElapsedX + 100000, ("%llu, %llu", cNsElapsed, cNsElapsedX)); /* the fudge factor is time drift */ uint32_t cAvgTicks = cNsElapsed / cNsInterval + 1; /* Check tick counts. ASSUMES no cpu on- or offlining. This only catches really bad stuff. */ uint32_t cMinTicks = cAvgTicks - cAvgTicks / 10; uint32_t cMaxTicks = cAvgTicks + cAvgTicks / 10 + 1; for (uint32_t iCpu = 0; iCpu < RTCPUSET_MAX_CPUS; iCpu++) if (paStates[iCpu].cTicks) { RTR0TESTR0_CHECK_MSG(RTCpuSetIsMemberByIndex(&OnlineSet, iCpu), ("%d\n", iCpu)); RTR0TESTR0_CHECK_MSG(paStates[iCpu].cTicks <= cMaxTicks && paStates[iCpu].cTicks >= cMinTicks, ("min=%u, ticks=%u, avg=%u max=%u, iCpu=%u, interval=%'u, elapsed=%'llu/%'llu\n", cMinTicks, paStates[iCpu].cTicks, cAvgTicks, cMaxTicks, iCpu, cNsInterval, cNsElapsed, cNsElapsedX)); } else RTR0TESTR0_CHECK_MSG(!RTCpuSetIsMemberByIndex(&OnlineSet, iCpu), ("%d\n", iCpu)); } RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); RTMemFree(paStates); break; } case TSTRTR0TIMER_LATENCY_OMNI: case TSTRTR0TIMER_LATENCY_OMNI_HIRES: { /* * Create a periodic timer running at max host frequency, but no more than 1000 Hz. */ PRTTIMER pTimer; uint32_t fFlags = (TSTRTR0TIMER_IS_HIRES(uOperation) ? RTTIMER_FLAGS_HIGH_RES : 0) | RTTIMER_FLAGS_CPU_ALL; uint32_t cNsInterval = cNsSysHz; while (cNsInterval < UINT32_C(1000000)) cNsInterval *= 2; int rc = RTTimerCreateEx(&pTimer, cNsInterval, fFlags, tstRTR0TimerCallbackLatencyOmni, NULL); if (rc == VERR_NOT_SUPPORTED) { RTR0TESTR0_SKIP_BREAK(); } RTR0TESTR0_CHECK_RC_BREAK(rc, VINF_SUCCESS); /* * Reset the state and run the test for 4 seconds. */ RT_ZERO(g_aOmniLatency); RTCPUSET OnlineSet; uint64_t uStartNsTS = RTTimeSystemNanoTS(); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStart(pTimer, 0), VINF_SUCCESS); RTMpGetOnlineSet(&OnlineSet); for (uint32_t i = 0; i < 5000 && RTTimeSystemNanoTS() - uStartNsTS <= UINT64_C(4000000000); i++) RTThreadSleep(2); RTR0TESTR0_CHECK_RC_BREAK(RTTimerStop(pTimer), VINF_SUCCESS); /* * Process the result. */ int32_t cNsLow = cNsInterval / 4 * 3; /* 75% */ int32_t cNsHigh = cNsInterval / 4 * 5; /* 125% */ uint32_t cTotal = 0; uint32_t cLow = 0; uint32_t cHigh = 0; for (uint32_t iCpu = 0; iCpu < RT_ELEMENTS(g_aOmniLatency); iCpu++) { uint32_t cSamples = g_aOmniLatency[iCpu].cSamples; if (cSamples > 1) { cTotal += cSamples - 1; for (uint32_t iSample = 1; iSample < cSamples; iSample++) { int64_t cNsDelta = g_aOmniLatency[iCpu].aSamples[iSample - 1].uNanoTs - g_aOmniLatency[iCpu].aSamples[iSample].uNanoTs; if (cNsDelta < cNsLow) cLow++; else if (cNsDelta > cNsHigh) cHigh++; } } } RTR0TestR0Info("125%%: %u; 75%%: %u; total: %u", cHigh, cLow, cTotal); RTR0TESTR0_CHECK_RC(RTTimerDestroy(pTimer), VINF_SUCCESS); break; } } RTR0TESTR0_SRV_REQ_EPILOG(pReqHdr); /* The error indicator is the '!' in the message buffer. */ return VINF_SUCCESS; }