/* $Id: tstCollector.cpp 106061 2024-09-16 14:03:52Z vboxsync $ */ /** @file * VirtualBox Main - Performance collector classes test cases. */ /* * Copyright (C) 2008-2024 Oracle and/or its affiliates. * * This file is part of VirtualBox base platform packages, as * available from https://www.virtualbox.org. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation, in version 3 of the * License. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, see . * * SPDX-License-Identifier: GPL-3.0-only */ #ifdef RT_OS_DARWIN # include "../src-server/darwin/PerformanceDarwin.cpp" #endif #ifdef RT_OS_FREEBSD # include "../src-server/freebsd/PerformanceFreeBSD.cpp" #endif #ifdef RT_OS_LINUX # include "../src-server/linux/PerformanceLinux.cpp" #endif #ifdef RT_OS_OS2 # include "../src-server/os2/PerformanceOS2.cpp" #endif #ifdef RT_OS_SOLARIS # include "../src-server/solaris/PerformanceSolaris.cpp" #endif #ifdef RT_OS_WINDOWS # define _WIN32_DCOM # include # include # include "../src-server/win/PerformanceWin.cpp" #endif #include #include #include #include #include #include #include #define RUN_TIME_MS 1000 #define N_CALLS(n, fn) \ do {\ for (int call = 0; call < n; ++call) \ rc = collector->fn; \ if (RT_FAILURE(rc)) \ RTPrintf("tstCollector: "#fn" -> %Rrc\n", rc); \ } while (0) #define CALLS_PER_SECOND(fn, args) \ do { \ nCalls = 0; \ start = RTTimeMilliTS(); \ do { \ rc = collector->fn args; \ if (RT_FAILURE(rc)) \ break; \ ++nCalls; \ } while (RTTimeMilliTS() - start < RUN_TIME_MS); \ if (RT_FAILURE(rc)) \ RTPrintf("tstCollector: "#fn" -> %Rrc\n", rc); \ else \ RTPrintf("%70s -- %u calls per second\n", #fn, nCalls); \ } while (0) static void shutdownProcessList(std::vector const &rProcesses) { for (size_t i = 0; i < rProcesses.size(); i++) RTProcTerminate(rProcesses[i]); } static void measurePerformance(pm::CollectorHAL *collector, const char *pszName, int cVMs) { const char * const args[] = { pszName, "-child", NULL }; pm::CollectorHints hints; std::vector processes; hints.collectHostCpuLoad(); hints.collectHostRamUsage(); /* Start fake VMs */ for (int i = 0; i < cVMs; ++i) { RTPROCESS pid; int rc = RTProcCreate(pszName, args, RTENV_DEFAULT, 0, &pid); if (RT_FAILURE(rc)) { hints.getProcesses(processes); shutdownProcessList(processes); RTPrintf("tstCollector: RTProcCreate() -> %Rrc\n", rc); return; } hints.collectProcessCpuLoad(pid); hints.collectProcessRamUsage(pid); } hints.getProcesses(processes); RTThreadSleep(30000); // Let children settle for half a minute int rc; ULONG tmp; uint64_t tmp64; uint64_t start; unsigned int nCalls; /* Pre-collect */ CALLS_PER_SECOND(preCollect, (hints, 0)); /* Host CPU load */ CALLS_PER_SECOND(getRawHostCpuLoad, (&tmp64, &tmp64, &tmp64)); /* Process CPU load */ CALLS_PER_SECOND(getRawProcessCpuLoad, (processes[nCalls % cVMs], &tmp64, &tmp64, &tmp64)); /* Host CPU speed */ CALLS_PER_SECOND(getHostCpuMHz, (&tmp)); /* Host RAM usage */ CALLS_PER_SECOND(getHostMemoryUsage, (&tmp, &tmp, &tmp)); /* Process RAM usage */ CALLS_PER_SECOND(getProcessMemoryUsage, (processes[nCalls % cVMs], &tmp)); start = RTTimeNanoTS(); int times; for (times = 0; times < 100; times++) { /* Pre-collect */ N_CALLS(1, preCollect(hints, 0)); /* Host CPU load */ N_CALLS(1, getRawHostCpuLoad(&tmp64, &tmp64, &tmp64)); /* Host CPU speed */ N_CALLS(1, getHostCpuMHz(&tmp)); /* Host RAM usage */ N_CALLS(1, getHostMemoryUsage(&tmp, &tmp, &tmp)); /* Process CPU load */ N_CALLS(cVMs, getRawProcessCpuLoad(processes[call], &tmp64, &tmp64, &tmp64)); /* Process RAM usage */ N_CALLS(cVMs, getProcessMemoryUsage(processes[call], &tmp)); } RTPrintf("\n%d VMs -- %u%% of CPU time\n", cVMs, (unsigned)((double)(RTTimeNanoTS() - start) / 10000000.0 / times)); /* Shut down fake VMs */ shutdownProcessList(processes); } #ifdef RT_OS_SOLARIS #define NETIFNAME "net0" #else #define NETIFNAME "eth0" #endif static int testNetwork(pm::CollectorHAL *collector) { pm::CollectorHints hints; uint64_t hostRxStart, hostTxStart; uint64_t hostRxStop, hostTxStop, speed = 125000000; /* Assume 1Gbit/s */ RTPrintf("tstCollector: TESTING - Network load, sleeping for 5 s...\n"); hostRxStart = hostTxStart = 0; int rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } rc = collector->getRawHostNetworkLoad(NETIFNAME, &hostRxStart, &hostTxStart); if (rc == VERR_NOT_IMPLEMENTED) RTPrintf("tstCollector: getRawHostNetworkLoad() not implemented, skipping\n"); else { if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostNetworkLoad() -> %Rrc\n", rc); return 1; } RTThreadSleep(5000); // Sleep for five seconds rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } hostRxStop = hostRxStart; hostTxStop = hostTxStart; rc = collector->getRawHostNetworkLoad(NETIFNAME, &hostRxStop, &hostTxStop); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostNetworkLoad() -> %Rrc\n", rc); return 1; } RTPrintf("tstCollector: host network speed = %llu bytes/sec (%llu mbit/sec)\n", speed, speed/(1000000/8)); RTPrintf("tstCollector: host network rx = %llu bytes/sec (%llu mbit/sec, %u.%u %%)\n", (hostRxStop - hostRxStart)/5, (hostRxStop - hostRxStart)/(5000000/8), (hostRxStop - hostRxStart) * 100 / (speed * 5), (hostRxStop - hostRxStart) * 10000 / (speed * 5) % 100); RTPrintf("tstCollector: host network tx = %llu bytes/sec (%llu mbit/sec, %u.%u %%)\n\n", (hostTxStop - hostTxStart)/5, (hostTxStop - hostTxStart)/(5000000/8), (hostTxStop - hostTxStart) * 100 / (speed * 5), (hostTxStop - hostTxStart) * 10000 / (speed * 5) % 100); } return 0; } #define FSNAME "/" static int testFsUsage(pm::CollectorHAL *collector) { RTPrintf("tstCollector: TESTING - File system usage\n"); ULONG total, used, available; int rc = collector->getHostFilesystemUsage(FSNAME, &total, &used, &available); if (rc == VERR_NOT_IMPLEMENTED) RTPrintf("tstCollector: getHostFilesystemUsage() not implemented, skipping\n"); else { if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getHostFilesystemUsage() -> %Rrc\n", rc); return 1; } RTPrintf("tstCollector: host root fs total = %lu MB\n", total); RTPrintf("tstCollector: host root fs used = %lu MB\n", used); RTPrintf("tstCollector: host root fs available = %lu MB\n\n", available); } return 0; } static int testDisk(pm::CollectorHAL *collector) { pm::CollectorHints hints; uint64_t diskMsStart, totalMsStart; uint64_t diskMsStop, totalMsStop; pm::DiskList disksUsage, disksLoad; int rc = collector->getDiskListByFs(FSNAME, disksUsage, disksLoad); if (rc == VERR_NOT_IMPLEMENTED) RTPrintf("tstCollector: getDiskListByFs() not implemented, skipping\n"); else { if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getDiskListByFs(%s) -> %Rrc\n", FSNAME, rc); return 1; } if (disksUsage.empty()) { RTPrintf("tstCollector: getDiskListByFs(%s) returned empty usage list\n", FSNAME); return 0; } if (disksLoad.empty()) { RTPrintf("tstCollector: getDiskListByFs(%s) returned empty usage list\n", FSNAME); return 0; } pm::DiskList::iterator it; for (it = disksUsage.begin(); it != disksUsage.end(); ++it) { uint64_t diskSize = 0; rc = collector->getHostDiskSize(it->c_str(), &diskSize); RTPrintf("tstCollector: TESTING - Disk size (%s) = %llu\n", it->c_str(), diskSize); if (rc == VERR_FILE_NOT_FOUND) RTPrintf("tstCollector: getHostDiskSize(%s) returned VERR_FILE_NOT_FOUND\n", it->c_str()); else if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getHostDiskSize() -> %Rrc\n", rc); return 1; } } for (it = disksLoad.begin(); it != disksLoad.end(); ++it) { RTPrintf("tstCollector: TESTING - Disk utilization (%s), sleeping for 5 s...\n", it->c_str()); hints.collectHostCpuLoad(); rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } rc = collector->getRawHostDiskLoad(it->c_str(), &diskMsStart, &totalMsStart); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostDiskLoad() -> %Rrc\n", rc); return 1; } RTThreadSleep(5000); // Sleep for five seconds rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } rc = collector->getRawHostDiskLoad(it->c_str(), &diskMsStop, &totalMsStop); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostDiskLoad() -> %Rrc\n", rc); return 1; } RTPrintf("tstCollector: host disk util = %llu msec (%u.%u %%), total = %llu msec\n\n", (diskMsStop - diskMsStart), (unsigned)((diskMsStop - diskMsStart) * 100 / (totalMsStop - totalMsStart)), (unsigned)((diskMsStop - diskMsStart) * 10000 / (totalMsStop - totalMsStart) % 100), totalMsStop - totalMsStart); } } return 0; } int main(int argc, char *argv[]) { bool cpuTest, ramTest, netTest, diskTest, fsTest, perfTest; cpuTest = ramTest = netTest = diskTest = fsTest = perfTest = false; /* * Initialize the VBox runtime without loading * the support driver. */ int rc = RTR3InitExe(argc, &argv, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: RTR3InitExe() -> %d\n", rc); return 1; } if (argc > 1) { if (!strcmp(argv[1], "-child")) { /* We have spawned ourselves as a child process -- scratch the leg */ RTThreadSleep(1000000); return 1; } for (int i = 1; i < argc; i++) { if (!strcmp(argv[i], "-cpu")) cpuTest = true; else if (!strcmp(argv[i], "-ram")) ramTest = true; else if (!strcmp(argv[i], "-net")) netTest = true; else if (!strcmp(argv[i], "-disk")) diskTest = true; else if (!strcmp(argv[i], "-fs")) fsTest = true; else if (!strcmp(argv[i], "-perf")) perfTest = true; else { RTPrintf("tstCollector: Unknown option: %s\n", argv[i]); return 2; } } } else cpuTest = ramTest = netTest = diskTest = fsTest = perfTest = true; #ifdef RT_OS_WINDOWS HRESULT hRes = CoInitialize(NULL); /* * Need to initialize security to access performance enumerators. */ hRes = CoInitializeSecurity( NULL, -1, NULL, NULL, RPC_C_AUTHN_LEVEL_NONE, RPC_C_IMP_LEVEL_IMPERSONATE, NULL, EOAC_NONE, 0); #endif pm::CollectorHAL *collector = pm::createHAL(); if (!collector) { RTPrintf("tstCollector: createMetricFactory() failed\n"); return 1; } pm::CollectorHints hints; if (cpuTest) { hints.collectHostCpuLoad(); hints.collectProcessCpuLoad(RTProcSelf()); } if (ramTest) { hints.collectHostRamUsage(); hints.collectProcessRamUsage(RTProcSelf()); } uint64_t start; uint64_t hostUserStart, hostKernelStart, hostIdleStart; uint64_t hostUserStop, hostKernelStop, hostIdleStop, hostTotal; uint64_t processUserStart, processKernelStart, processTotalStart; uint64_t processUserStop, processKernelStop, processTotalStop; rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } if (cpuTest) { RTPrintf("tstCollector: TESTING - CPU load, sleeping for 5 s...\n"); rc = collector->getRawHostCpuLoad(&hostUserStart, &hostKernelStart, &hostIdleStart); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostCpuLoad() -> %Rrc\n", rc); return 1; } rc = collector->getRawProcessCpuLoad(RTProcSelf(), &processUserStart, &processKernelStart, &processTotalStart); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawProcessCpuLoad() -> %Rrc\n", rc); return 1; } RTThreadSleep(5000); // Sleep for 5 seconds rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } rc = collector->getRawHostCpuLoad(&hostUserStop, &hostKernelStop, &hostIdleStop); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostCpuLoad() -> %Rrc\n", rc); return 1; } rc = collector->getRawProcessCpuLoad(RTProcSelf(), &processUserStop, &processKernelStop, &processTotalStop); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawProcessCpuLoad() -> %Rrc\n", rc); return 1; } hostTotal = hostUserStop - hostUserStart + hostKernelStop - hostKernelStart + hostIdleStop - hostIdleStart; RTPrintf("tstCollector: host cpu user = %u.%u %%\n", (unsigned)((hostUserStop - hostUserStart) * 100 / hostTotal), (unsigned)((hostUserStop - hostUserStart) * 10000 / hostTotal % 100)); RTPrintf("tstCollector: host cpu kernel = %u.%u %%\n", (unsigned)((hostKernelStop - hostKernelStart) * 100 / hostTotal), (unsigned)((hostKernelStop - hostKernelStart) * 10000 / hostTotal % 100)); RTPrintf("tstCollector: host cpu idle = %u.%u %%\n", (unsigned)((hostIdleStop - hostIdleStart) * 100 / hostTotal), (unsigned)((hostIdleStop - hostIdleStart) * 10000 / hostTotal % 100)); RTPrintf("tstCollector: process cpu user = %u.%u %%\n", (unsigned)((processUserStop - processUserStart) * 100 / (processTotalStop - processTotalStart)), (unsigned)((processUserStop - processUserStart) * 10000 / (processTotalStop - processTotalStart) % 100)); RTPrintf("tstCollector: process cpu kernel = %u.%u %%\n\n", (unsigned)((processKernelStop - processKernelStart) * 100 / (processTotalStop - processTotalStart)), (unsigned)((processKernelStop - processKernelStart) * 10000 / (processTotalStop - processTotalStart) % 100)); RTPrintf("tstCollector: TESTING - CPU load, looping for 5 s...\n"); rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } rc = collector->getRawHostCpuLoad(&hostUserStart, &hostKernelStart, &hostIdleStart); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostCpuLoad() -> %Rrc\n", rc); return 1; } rc = collector->getRawProcessCpuLoad(RTProcSelf(), &processUserStart, &processKernelStart, &processTotalStart); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawProcessCpuLoad() -> %Rrc\n", rc); return 1; } start = RTTimeMilliTS(); while (RTTimeMilliTS() - start < 5000) ; // Loop for 5 seconds rc = collector->preCollect(hints, 0); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: preCollect() -> %Rrc\n", rc); return 1; } rc = collector->getRawHostCpuLoad(&hostUserStop, &hostKernelStop, &hostIdleStop); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawHostCpuLoad() -> %Rrc\n", rc); return 1; } rc = collector->getRawProcessCpuLoad(RTProcSelf(), &processUserStop, &processKernelStop, &processTotalStop); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getRawProcessCpuLoad() -> %Rrc\n", rc); return 1; } hostTotal = hostUserStop - hostUserStart + hostKernelStop - hostKernelStart + hostIdleStop - hostIdleStart; RTPrintf("tstCollector: host cpu user = %u.%u %%\n", (unsigned)((hostUserStop - hostUserStart) * 100 / hostTotal), (unsigned)((hostUserStop - hostUserStart) * 10000 / hostTotal % 100)); RTPrintf("tstCollector: host cpu kernel = %u.%u %%\n", (unsigned)((hostKernelStop - hostKernelStart) * 100 / hostTotal), (unsigned)((hostKernelStop - hostKernelStart) * 10000 / hostTotal % 100)); RTPrintf("tstCollector: host cpu idle = %u.%u %%\n", (unsigned)((hostIdleStop - hostIdleStart) * 100 / hostTotal), (unsigned)((hostIdleStop - hostIdleStart) * 10000 / hostTotal % 100)); RTPrintf("tstCollector: process cpu user = %u.%u %%\n", (unsigned)((processUserStop - processUserStart) * 100 / (processTotalStop - processTotalStart)), (unsigned)((processUserStop - processUserStart) * 10000 / (processTotalStop - processTotalStart) % 100)); RTPrintf("tstCollector: process cpu kernel = %u.%u %%\n\n", (unsigned)((processKernelStop - processKernelStart) * 100 / (processTotalStop - processTotalStart)), (unsigned)((processKernelStop - processKernelStart) * 10000 / (processTotalStop - processTotalStart) % 100)); } if (ramTest) { RTPrintf("tstCollector: TESTING - Memory usage\n"); ULONG total, used, available, processUsed; rc = collector->getHostMemoryUsage(&total, &used, &available); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getHostMemoryUsage() -> %Rrc\n", rc); return 1; } rc = collector->getProcessMemoryUsage(RTProcSelf(), &processUsed); if (RT_FAILURE(rc)) { RTPrintf("tstCollector: getProcessMemoryUsage() -> %Rrc\n", rc); return 1; } RTPrintf("tstCollector: host mem total = %lu kB\n", total); RTPrintf("tstCollector: host mem used = %lu kB\n", used); RTPrintf("tstCollector: host mem available = %lu kB\n", available); RTPrintf("tstCollector: process mem used = %lu kB\n\n", processUsed); } if (netTest) rc = testNetwork(collector); if (fsTest) rc = testFsUsage(collector); if (diskTest) rc = testDisk(collector); if (perfTest) { RTPrintf("tstCollector: TESTING - Performance\n\n"); measurePerformance(collector, argv[0], 100); } delete collector; RTPrintf("\ntstCollector FINISHED.\n"); return RTEXITCODE_SUCCESS; }