btrfs: Attempt to fix GCC2 build.
[haiku.git] / src / system / kernel / scheduler / scheduler_tracing.cpp
blob21eab8a0a83e7f088ceb7bfaf3204529ce8fff5a
1 /*
2 * Copyright 2008, Ingo Weinhold, ingo_weinhold@gmx.de.
3 * Copyright 2002-2007, Axel Dörfler, axeld@pinc-software.de.
4 * Distributed under the terms of the MIT License.
5 */
7 #include "scheduler_tracing.h"
9 #include <debug.h>
12 #if SCHEDULER_TRACING
14 namespace SchedulerTracing {
16 // #pragma mark - EnqueueThread
19 void
20 EnqueueThread::AddDump(TraceOutput& out)
22 out.Print("scheduler enqueue %ld \"%s\", effective priority %d, "
23 "real priority %d", fID, fName, fEffectivePriority, fPriority);
27 const char*
28 EnqueueThread::Name() const
30 return fName;
34 // #pragma mark - RemoveThread
37 void
38 RemoveThread::AddDump(TraceOutput& out)
40 out.Print("scheduler remove %ld, priority %d", fID, fPriority);
43 const char*
44 RemoveThread::Name() const
46 return NULL;
50 // #pragma mark - ScheduleThread
53 void
54 ScheduleThread::AddDump(TraceOutput& out)
56 out.Print("schedule %ld \"%s\", priority %d, CPU %ld, "
57 "previous thread: %ld (", fID, fName, fPriority, fCPU, fPreviousID);
58 if (fPreviousState == B_THREAD_WAITING) {
59 switch (fPreviousWaitObjectType) {
60 case THREAD_BLOCK_TYPE_SEMAPHORE:
61 out.Print("sem %ld", (sem_id)(addr_t)fPreviousWaitObject);
62 break;
63 case THREAD_BLOCK_TYPE_CONDITION_VARIABLE:
64 out.Print("cvar %p", fPreviousWaitObject);
65 break;
66 case THREAD_BLOCK_TYPE_SNOOZE:
67 out.Print("snooze()");
68 break;
69 case THREAD_BLOCK_TYPE_SIGNAL:
70 out.Print("signal");
71 break;
72 case THREAD_BLOCK_TYPE_MUTEX:
73 out.Print("mutex %p", fPreviousWaitObject);
74 break;
75 case THREAD_BLOCK_TYPE_RW_LOCK:
76 out.Print("rwlock %p", fPreviousWaitObject);
77 break;
78 case THREAD_BLOCK_TYPE_OTHER:
79 out.Print("other (%p)", fPreviousWaitObject);
80 // We could print the string, but it might come from a
81 // kernel module that has already been unloaded.
82 break;
83 default:
84 out.Print("unknown (%p)", fPreviousWaitObject);
85 break;
87 #if SCHEDULER_TRACING >= 2
88 } else if (fPreviousState == B_THREAD_READY) {
89 out.Print("ready at %p", fPreviousPC);
90 #endif
91 } else
92 out.Print("%s", thread_state_to_text(NULL, fPreviousState));
94 out.Print(")");
98 const char*
99 ScheduleThread::Name() const
101 return fName;
104 } // namespace SchedulerTracing
107 // #pragma mark -
111 cmd_scheduler(int argc, char** argv)
113 using namespace SchedulerTracing;
115 int64 threadID;
116 if (argc != 2
117 || !evaluate_debug_expression(argv[1], (uint64*)&threadID, true)) {
118 print_debugger_command_usage(argv[0]);
119 return 0;
122 if (threadID <= 0) {
123 kprintf("Invalid thread ID: %lld\n", threadID);
124 return 0;
127 ScheduleState state = UNKNOWN;
128 bigtime_t lastTime = 0;
130 int64 runs = 0;
131 bigtime_t totalRunTime = 0;
132 bigtime_t minRunTime = -1;
133 bigtime_t maxRunTime = -1;
135 int64 latencies = 0;
136 bigtime_t totalLatency = 0;
137 bigtime_t minLatency = -1;
138 bigtime_t maxLatency = -1;
139 int32 maxLatencyEntry = -1;
141 int64 reruns = 0;
142 bigtime_t totalRerunTime = 0;
143 bigtime_t minRerunTime = -1;
144 bigtime_t maxRerunTime = -1;
145 int32 maxRerunEntry = -1;
147 int64 preemptions = 0;
149 TraceEntryIterator iterator;
150 while (TraceEntry* _entry = iterator.Next()) {
151 if (dynamic_cast<SchedulerTraceEntry*>(_entry) == NULL)
152 continue;
154 if (ScheduleThread* entry = dynamic_cast<ScheduleThread*>(_entry)) {
155 if (entry->ThreadID() == threadID) {
156 // thread scheduled
157 bigtime_t diffTime = entry->Time() - lastTime;
159 if (state == READY) {
160 // thread scheduled after having been woken up
161 latencies++;
162 totalLatency += diffTime;
163 if (minLatency < 0 || diffTime < minLatency)
164 minLatency = diffTime;
165 if (diffTime > maxLatency) {
166 maxLatency = diffTime;
167 maxLatencyEntry = iterator.Index();
169 } else if (state == PREEMPTED) {
170 // thread scheduled after having been preempted before
171 reruns++;
172 totalRerunTime += diffTime;
173 if (minRerunTime < 0 || diffTime < minRerunTime)
174 minRerunTime = diffTime;
175 if (diffTime > maxRerunTime) {
176 maxRerunTime = diffTime;
177 maxRerunEntry = iterator.Index();
181 if (state == STILL_RUNNING) {
182 // Thread was running and continues to run.
183 state = RUNNING;
186 if (state != RUNNING) {
187 lastTime = entry->Time();
188 state = RUNNING;
190 } else if (entry->PreviousThreadID() == threadID) {
191 // thread unscheduled
192 bigtime_t diffTime = entry->Time() - lastTime;
194 if (state == STILL_RUNNING) {
195 // thread preempted
196 runs++;
197 preemptions++;
198 totalRunTime += diffTime;
199 if (minRunTime < 0 || diffTime < minRunTime)
200 minRunTime = diffTime;
201 if (diffTime > maxRunTime)
202 maxRunTime = diffTime;
204 state = PREEMPTED;
205 lastTime = entry->Time();
206 } else if (state == RUNNING) {
207 // thread starts waiting (it hadn't been added to the run
208 // queue before being unscheduled)
209 bigtime_t diffTime = entry->Time() - lastTime;
210 runs++;
211 totalRunTime += diffTime;
212 if (minRunTime < 0 || diffTime < minRunTime)
213 minRunTime = diffTime;
214 if (diffTime > maxRunTime)
215 maxRunTime = diffTime;
217 state = WAITING;
218 lastTime = entry->Time();
221 } else if (EnqueueThread* entry
222 = dynamic_cast<EnqueueThread*>(_entry)) {
223 if (entry->ThreadID() != threadID)
224 continue;
226 // thread enqueued in run queue
228 if (state == RUNNING || state == STILL_RUNNING) {
229 // Thread was running and is reentered into the run queue. This
230 // is done by the scheduler, if the thread remains ready.
231 state = STILL_RUNNING;
232 } else {
233 // Thread was waiting and is ready now.
234 lastTime = entry->Time();
235 state = READY;
237 } else if (RemoveThread* entry = dynamic_cast<RemoveThread*>(_entry)) {
238 if (entry->ThreadID() != threadID)
239 continue;
241 // thread removed from run queue
243 // This really only happens when the thread priority is changed
244 // while the thread is ready.
246 if (state == RUNNING) {
247 // This should never happen.
248 bigtime_t diffTime = entry->Time() - lastTime;
249 runs++;
250 totalRunTime += diffTime;
251 if (minRunTime < 0 || diffTime < minRunTime)
252 minRunTime = diffTime;
253 if (diffTime > maxRunTime)
254 maxRunTime = diffTime;
257 state = WAITING;
261 // print results
262 if (runs == 0) {
263 kprintf("thread %lld never ran.\n", threadID);
264 return 0;
267 kprintf("scheduling statistics for thread %lld:\n", threadID);
268 kprintf("runs:\n");
269 kprintf(" total #: %lld\n", runs);
270 kprintf(" total: %lld us\n", totalRunTime);
271 kprintf(" average: %#.2f us\n", (double)totalRunTime / runs);
272 kprintf(" min: %lld us\n", minRunTime);
273 kprintf(" max: %lld us\n", maxRunTime);
275 if (latencies > 0) {
276 kprintf("scheduling latency after wake up:\n");
277 kprintf(" total #: %lld\n", latencies);
278 kprintf(" total: %lld us\n", totalLatency);
279 kprintf(" average: %#.2f us\n", (double)totalLatency / latencies);
280 kprintf(" min: %lld us\n", minLatency);
281 kprintf(" max: %lld us\n", maxLatency);
282 kprintf(" max: %lld us (at tracing entry %ld)\n", maxLatency,
283 maxLatencyEntry);
284 } else
285 kprintf("thread was never run after having been woken up\n");
287 if (reruns > 0) {
288 kprintf("scheduling latency after preemption:\n");
289 kprintf(" total #: %lld\n", reruns);
290 kprintf(" total: %lld us\n", totalRerunTime);
291 kprintf(" average: %#.2f us\n", (double)totalRerunTime / reruns);
292 kprintf(" min: %lld us\n", minRerunTime);
293 kprintf(" max: %lld us (at tracing entry %ld)\n", maxRerunTime,
294 maxRerunEntry);
295 } else
296 kprintf("thread was never rerun after preemption\n");
298 if (preemptions > 0)
299 kprintf("thread was preempted %lld times\n", preemptions);
300 else
301 kprintf("thread was never preempted\n");
303 return 0;
306 #endif // SCHEDULER_TRACING