1 ftrace - Function Tracer
2 ========================
4 Copyright 2008 Red Hat Inc.
5 Author: Steven Rostedt <srostedt@redhat.com>
6 License: The GNU Free Documentation License, Version 1.2
7 (dual licensed under the GPL v2)
8 Reviewers: Elias Oltmanns, Randy Dunlap, Andrew Morton,
9 John Kacur, and David Teigland.
10 Written for: 2.6.28-rc2
15 Ftrace is an internal tracer designed to help out developers and
16 designers of systems to find what is going on inside the kernel.
17 It can be used for debugging or analyzing latencies and
18 performance issues that take place outside of user-space.
20 Although ftrace is the function tracer, it also includes an
21 infrastructure that allows for other types of tracing. Some of
22 the tracers that are currently in ftrace include a tracer to
23 trace context switches, the time it takes for a high priority
24 task to run after it was woken up, the time interrupts are
25 disabled, and more (ftrace allows for tracer plugins, which
26 means that the list of tracers can always grow).
29 Implementation Details
30 ----------------------
32 See ftrace-design.txt for details for arch porters and such.
38 Ftrace uses the debugfs file system to hold the control files as
39 well as the files to display output.
41 When debugfs is configured into the kernel (which selecting any ftrace
42 option will do) the directory /sys/kernel/debug will be created. To mount
43 this directory, you can add to your /etc/fstab file:
45 debugfs /sys/kernel/debug debugfs defaults 0 0
47 Or you can mount it at run time with:
49 mount -t debugfs nodev /sys/kernel/debug
51 For quicker access to that directory you may want to make a soft link to
54 ln -s /sys/kernel/debug /debug
56 Any selected ftrace option will also create a directory called tracing
57 within the debugfs. The rest of the document will assume that you are in
58 the ftrace directory (cd /sys/kernel/debug/tracing) and will only concentrate
59 on the files within that directory and not distract from the content with
60 the extended "/sys/kernel/debug/tracing" path name.
62 That's it! (assuming that you have ftrace configured into your kernel)
64 After mounting the debugfs, you can see a directory called
65 "tracing". This directory contains the control and output files
66 of ftrace. Here is a list of some of the key files:
69 Note: all time values are in microseconds.
73 This is used to set or display the current tracer
78 This holds the different types of tracers that
79 have been compiled into the kernel. The
80 tracers listed here can be configured by
81 echoing their name into current_tracer.
85 This sets or displays whether the current_tracer
86 is activated and tracing or not. Echo 0 into this
87 file to disable the tracer or 1 to enable it.
91 This file holds the output of the trace in a human
92 readable format (described below).
96 The output is the same as the "trace" file but this
97 file is meant to be streamed with live tracing.
98 Reads from this file will block until new data is
99 retrieved. Unlike the "trace" file, this file is a
100 consumer. This means reading from this file causes
101 sequential reads to display more current data. Once
102 data is read from this file, it is consumed, and
103 will not be read again with a sequential read. The
104 "trace" file is static, and if the tracer is not
105 adding more data,they will display the same
106 information every time they are read.
110 This file lets the user control the amount of data
111 that is displayed in one of the above output
116 Some of the tracers record the max latency.
117 For example, the time interrupts are disabled.
118 This time is saved in this file. The max trace
119 will also be stored, and displayed by "trace".
120 A new max trace will only be recorded if the
121 latency is greater than the value in this
122 file. (in microseconds)
126 This sets or displays the number of kilobytes each CPU
127 buffer can hold. The tracer buffers are the same size
128 for each CPU. The displayed number is the size of the
129 CPU buffer and not total size of all buffers. The
130 trace buffers are allocated in pages (blocks of memory
131 that the kernel uses for allocation, usually 4 KB in size).
132 If the last page allocated has room for more bytes
133 than requested, the rest of the page will be used,
134 making the actual allocation bigger than requested.
135 ( Note, the size may not be a multiple of the page size
136 due to buffer management overhead. )
138 This can only be updated when the current_tracer
143 This is a mask that lets the user only trace
144 on specified CPUS. The format is a hex string
145 representing the CPUS.
149 When dynamic ftrace is configured in (see the
150 section below "dynamic ftrace"), the code is dynamically
151 modified (code text rewrite) to disable calling of the
152 function profiler (mcount). This lets tracing be configured
153 in with practically no overhead in performance. This also
154 has a side effect of enabling or disabling specific functions
155 to be traced. Echoing names of functions into this file
156 will limit the trace to only those functions.
158 This interface also allows for commands to be used. See the
159 "Filter commands" section for more details.
163 This has an effect opposite to that of
164 set_ftrace_filter. Any function that is added here will not
165 be traced. If a function exists in both set_ftrace_filter
166 and set_ftrace_notrace, the function will _not_ be traced.
170 Have the function tracer only trace a single thread.
174 Set a "trigger" function where tracing should start
175 with the function graph tracer (See the section
176 "dynamic ftrace" for more details).
178 available_filter_functions:
180 This lists the functions that ftrace
181 has processed and can trace. These are the function
182 names that you can pass to "set_ftrace_filter" or
183 "set_ftrace_notrace". (See the section "dynamic ftrace"
184 below for more details.)
190 Here is the list of current tracers that may be configured.
194 Function call tracer to trace all kernel functions.
198 Similar to the function tracer except that the
199 function tracer probes the functions on their entry
200 whereas the function graph tracer traces on both entry
201 and exit of the functions. It then provides the ability
202 to draw a graph of function calls similar to C code
207 Traces the context switches and wakeups between tasks.
211 Traces the areas that disable interrupts and saves
212 the trace with the longest max latency.
213 See tracing_max_latency. When a new max is recorded,
214 it replaces the old trace. It is best to view this
215 trace with the latency-format option enabled.
219 Similar to irqsoff but traces and records the amount of
220 time for which preemption is disabled.
224 Similar to irqsoff and preemptoff, but traces and
225 records the largest time for which irqs and/or preemption
230 Traces and records the max latency that it takes for
231 the highest priority task to get scheduled after
232 it has been woken up.
236 Uses the BTS CPU feature on x86 CPUs to traces all
241 This is the "trace nothing" tracer. To remove all
242 tracers from tracing simply echo "nop" into
246 Examples of using the tracer
247 ----------------------------
249 Here are typical examples of using the tracers when controlling
250 them only with the debugfs interface (without using any
251 user-land utilities).
256 Here is an example of the output format of the file "trace"
261 # TASK-PID CPU# TIMESTAMP FUNCTION
263 bash-4251 [01] 10152.583854: path_put <-path_walk
264 bash-4251 [01] 10152.583855: dput <-path_put
265 bash-4251 [01] 10152.583855: _atomic_dec_and_lock <-dput
268 A header is printed with the tracer name that is represented by
269 the trace. In this case the tracer is "function". Then a header
270 showing the format. Task name "bash", the task PID "4251", the
271 CPU that it was running on "01", the timestamp in <secs>.<usecs>
272 format, the function name that was traced "path_put" and the
273 parent function that called this function "path_walk". The
274 timestamp is the time at which the function was entered.
276 The sched_switch tracer also includes tracing of task wakeups
277 and context switches.
279 ksoftirqd/1-7 [01] 1453.070013: 7:115:R + 2916:115:S
280 ksoftirqd/1-7 [01] 1453.070013: 7:115:R + 10:115:S
281 ksoftirqd/1-7 [01] 1453.070013: 7:115:R ==> 10:115:R
282 events/1-10 [01] 1453.070013: 10:115:S ==> 2916:115:R
283 kondemand/1-2916 [01] 1453.070013: 2916:115:S ==> 7:115:R
284 ksoftirqd/1-7 [01] 1453.070013: 7:115:S ==> 0:140:R
286 Wake ups are represented by a "+" and the context switches are
287 shown as "==>". The format is:
291 Previous task Next Task
293 <pid>:<prio>:<state> ==> <pid>:<prio>:<state>
297 Current task Task waking up
299 <pid>:<prio>:<state> + <pid>:<prio>:<state>
301 The prio is the internal kernel priority, which is the inverse
302 of the priority that is usually displayed by user-space tools.
303 Zero represents the highest priority (99). Prio 100 starts the
304 "nice" priorities with 100 being equal to nice -20 and 139 being
305 nice 19. The prio "140" is reserved for the idle task which is
306 the lowest priority thread (pid 0).
312 When the latency-format option is enabled, the trace file gives
313 somewhat more information to see why a latency happened.
314 Here is a typical trace.
318 irqsoff latency trace v1.1.5 on 2.6.26-rc8
319 --------------------------------------------------------------------
320 latency: 97 us, #3/3, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
322 | task: swapper-0 (uid:0 nice:0 policy:0 rt_prio:0)
324 => started at: apic_timer_interrupt
325 => ended at: do_softirq
328 # / _-----=> irqs-off
329 # | / _----=> need-resched
330 # || / _---=> hardirq/softirq
331 # ||| / _--=> preempt-depth
334 # cmd pid ||||| time | caller
336 <idle>-0 0d..1 0us+: trace_hardirqs_off_thunk (apic_timer_interrupt)
337 <idle>-0 0d.s. 97us : __do_softirq (do_softirq)
338 <idle>-0 0d.s1 98us : trace_hardirqs_on (do_softirq)
341 This shows that the current tracer is "irqsoff" tracing the time
342 for which interrupts were disabled. It gives the trace version
343 and the version of the kernel upon which this was executed on
344 (2.6.26-rc8). Then it displays the max latency in microsecs (97
345 us). The number of trace entries displayed and the total number
346 recorded (both are three: #3/3). The type of preemption that was
347 used (PREEMPT). VP, KP, SP, and HP are always zero and are
348 reserved for later use. #P is the number of online CPUS (#P:2).
350 The task is the process that was running when the latency
351 occurred. (swapper pid: 0).
353 The start and stop (the functions in which the interrupts were
354 disabled and enabled respectively) that caused the latencies:
356 apic_timer_interrupt is where the interrupts were disabled.
357 do_softirq is where they were enabled again.
359 The next lines after the header are the trace itself. The header
360 explains which is which.
362 cmd: The name of the process in the trace.
364 pid: The PID of that process.
366 CPU#: The CPU which the process was running on.
368 irqs-off: 'd' interrupts are disabled. '.' otherwise.
369 Note: If the architecture does not support a way to
370 read the irq flags variable, an 'X' will always
373 need-resched: 'N' task need_resched is set, '.' otherwise.
376 'H' - hard irq occurred inside a softirq.
377 'h' - hard irq is running
378 's' - soft irq is running
379 '.' - normal context.
381 preempt-depth: The level of preempt_disabled
383 The above is mostly meaningful for kernel developers.
385 time: When the latency-format option is enabled, the trace file
386 output includes a timestamp relative to the start of the
387 trace. This differs from the output when latency-format
388 is disabled, which includes an absolute timestamp.
390 delay: This is just to help catch your eye a bit better. And
391 needs to be fixed to be only relative to the same CPU.
392 The marks are determined by the difference between this
393 current trace and the next trace.
394 '!' - greater than preempt_mark_thresh (default 100)
395 '+' - greater than 1 microsecond
396 ' ' - less than or equal to 1 microsecond.
398 The rest is the same as the 'trace' file.
404 The trace_options file is used to control what gets printed in
405 the trace output. To see what is available, simply cat the file:
408 print-parent nosym-offset nosym-addr noverbose noraw nohex nobin \
409 noblock nostacktrace nosched-tree nouserstacktrace nosym-userobj
411 To disable one of the options, echo in the option prepended with
414 echo noprint-parent > trace_options
416 To enable an option, leave off the "no".
418 echo sym-offset > trace_options
420 Here are the available options:
422 print-parent - On function traces, display the calling (parent)
423 function as well as the function being traced.
426 bash-4000 [01] 1477.606694: simple_strtoul <-strict_strtoul
429 bash-4000 [01] 1477.606694: simple_strtoul
432 sym-offset - Display not only the function name, but also the
433 offset in the function. For example, instead of
434 seeing just "ktime_get", you will see
435 "ktime_get+0xb/0x20".
438 bash-4000 [01] 1477.606694: simple_strtoul+0x6/0xa0
440 sym-addr - this will also display the function address as well
441 as the function name.
444 bash-4000 [01] 1477.606694: simple_strtoul <c0339346>
446 verbose - This deals with the trace file when the
447 latency-format option is enabled.
449 bash 4000 1 0 00000000 00010a95 [58127d26] 1720.415ms \
450 (+0.000ms): simple_strtoul (strict_strtoul)
452 raw - This will display raw numbers. This option is best for
453 use with user applications that can translate the raw
454 numbers better than having it done in the kernel.
456 hex - Similar to raw, but the numbers will be in a hexadecimal
459 bin - This will print out the formats in raw binary.
461 block - TBD (needs update)
463 stacktrace - This is one of the options that changes the trace
464 itself. When a trace is recorded, so is the stack
465 of functions. This allows for back traces of
468 userstacktrace - This option changes the trace. It records a
469 stacktrace of the current userspace thread.
471 sym-userobj - when user stacktrace are enabled, look up which
472 object the address belongs to, and print a
473 relative address. This is especially useful when
474 ASLR is on, otherwise you don't get a chance to
475 resolve the address to object/file/line after
476 the app is no longer running
478 The lookup is performed when you read
479 trace,trace_pipe. Example:
481 a.out-1623 [000] 40874.465068: /root/a.out[+0x480] <-/root/a.out[+0
482 x494] <- /root/a.out[+0x4a8] <- /lib/libc-2.7.so[+0x1e1a6]
484 sched-tree - trace all tasks that are on the runqueue, at
485 every scheduling event. Will add overhead if
486 there's a lot of tasks running at once.
488 latency-format - This option changes the trace. When
489 it is enabled, the trace displays
490 additional information about the
491 latencies, as described in "Latency
497 This tracer simply records schedule switches. Here is an example
500 # echo sched_switch > current_tracer
501 # echo 1 > tracing_enabled
503 # echo 0 > tracing_enabled
506 # tracer: sched_switch
508 # TASK-PID CPU# TIMESTAMP FUNCTION
510 bash-3997 [01] 240.132281: 3997:120:R + 4055:120:R
511 bash-3997 [01] 240.132284: 3997:120:R ==> 4055:120:R
512 sleep-4055 [01] 240.132371: 4055:120:S ==> 3997:120:R
513 bash-3997 [01] 240.132454: 3997:120:R + 4055:120:S
514 bash-3997 [01] 240.132457: 3997:120:R ==> 4055:120:R
515 sleep-4055 [01] 240.132460: 4055:120:D ==> 3997:120:R
516 bash-3997 [01] 240.132463: 3997:120:R + 4055:120:D
517 bash-3997 [01] 240.132465: 3997:120:R ==> 4055:120:R
518 <idle>-0 [00] 240.132589: 0:140:R + 4:115:S
519 <idle>-0 [00] 240.132591: 0:140:R ==> 4:115:R
520 ksoftirqd/0-4 [00] 240.132595: 4:115:S ==> 0:140:R
521 <idle>-0 [00] 240.132598: 0:140:R + 4:115:S
522 <idle>-0 [00] 240.132599: 0:140:R ==> 4:115:R
523 ksoftirqd/0-4 [00] 240.132603: 4:115:S ==> 0:140:R
524 sleep-4055 [01] 240.133058: 4055:120:S ==> 3997:120:R
528 As we have discussed previously about this format, the header
529 shows the name of the trace and points to the options. The
530 "FUNCTION" is a misnomer since here it represents the wake ups
531 and context switches.
533 The sched_switch file only lists the wake ups (represented with
534 '+') and context switches ('==>') with the previous task or
535 current task first followed by the next task or task waking up.
536 The format for both of these is PID:KERNEL-PRIO:TASK-STATE.
537 Remember that the KERNEL-PRIO is the inverse of the actual
538 priority with zero (0) being the highest priority and the nice
539 values starting at 100 (nice -20). Below is a quick chart to map
540 the kernel priority to user land priorities.
542 Kernel Space User Space
543 ===============================================================
544 0(high) to 98(low) user RT priority 99(high) to 1(low)
545 with SCHED_RR or SCHED_FIFO
546 ---------------------------------------------------------------
547 99 sched_priority is not used in scheduling
548 decisions(it must be specified as 0)
549 ---------------------------------------------------------------
550 100(high) to 139(low) user nice -20(high) to 19(low)
551 ---------------------------------------------------------------
552 140 idle task priority
553 ---------------------------------------------------------------
557 R - running : wants to run, may not actually be running
558 S - sleep : process is waiting to be woken up (handles signals)
559 D - disk sleep (uninterruptible sleep) : process must be woken up
561 T - stopped : process suspended
562 t - traced : process is being traced (with something like gdb)
563 Z - zombie : process waiting to be cleaned up
570 The following tracers (listed below) give different output
571 depending on whether or not the sysctl ftrace_enabled is set. To
572 set ftrace_enabled, one can either use the sysctl function or
573 set it via the proc file system interface.
575 sysctl kernel.ftrace_enabled=1
579 echo 1 > /proc/sys/kernel/ftrace_enabled
581 To disable ftrace_enabled simply replace the '1' with '0' in the
584 When ftrace_enabled is set the tracers will also record the
585 functions that are within the trace. The descriptions of the
586 tracers will also show an example with ftrace enabled.
592 When interrupts are disabled, the CPU can not react to any other
593 external event (besides NMIs and SMIs). This prevents the timer
594 interrupt from triggering or the mouse interrupt from letting
595 the kernel know of a new mouse event. The result is a latency
596 with the reaction time.
598 The irqsoff tracer tracks the time for which interrupts are
599 disabled. When a new maximum latency is hit, the tracer saves
600 the trace leading up to that latency point so that every time a
601 new maximum is reached, the old saved trace is discarded and the
604 To reset the maximum, echo 0 into tracing_max_latency. Here is
607 # echo irqsoff > current_tracer
608 # echo latency-format > trace_options
609 # echo 0 > tracing_max_latency
610 # echo 1 > tracing_enabled
613 # echo 0 > tracing_enabled
617 irqsoff latency trace v1.1.5 on 2.6.26
618 --------------------------------------------------------------------
619 latency: 12 us, #3/3, CPU#1 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
621 | task: bash-3730 (uid:0 nice:0 policy:0 rt_prio:0)
623 => started at: sys_setpgid
624 => ended at: sys_setpgid
627 # / _-----=> irqs-off
628 # | / _----=> need-resched
629 # || / _---=> hardirq/softirq
630 # ||| / _--=> preempt-depth
633 # cmd pid ||||| time | caller
635 bash-3730 1d... 0us : _write_lock_irq (sys_setpgid)
636 bash-3730 1d..1 1us+: _write_unlock_irq (sys_setpgid)
637 bash-3730 1d..2 14us : trace_hardirqs_on (sys_setpgid)
640 Here we see that that we had a latency of 12 microsecs (which is
641 very good). The _write_lock_irq in sys_setpgid disabled
642 interrupts. The difference between the 12 and the displayed
643 timestamp 14us occurred because the clock was incremented
644 between the time of recording the max latency and the time of
645 recording the function that had that latency.
647 Note the above example had ftrace_enabled not set. If we set the
648 ftrace_enabled, we get a much larger output:
652 irqsoff latency trace v1.1.5 on 2.6.26-rc8
653 --------------------------------------------------------------------
654 latency: 50 us, #101/101, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
656 | task: ls-4339 (uid:0 nice:0 policy:0 rt_prio:0)
658 => started at: __alloc_pages_internal
659 => ended at: __alloc_pages_internal
662 # / _-----=> irqs-off
663 # | / _----=> need-resched
664 # || / _---=> hardirq/softirq
665 # ||| / _--=> preempt-depth
668 # cmd pid ||||| time | caller
670 ls-4339 0...1 0us+: get_page_from_freelist (__alloc_pages_internal)
671 ls-4339 0d..1 3us : rmqueue_bulk (get_page_from_freelist)
672 ls-4339 0d..1 3us : _spin_lock (rmqueue_bulk)
673 ls-4339 0d..1 4us : add_preempt_count (_spin_lock)
674 ls-4339 0d..2 4us : __rmqueue (rmqueue_bulk)
675 ls-4339 0d..2 5us : __rmqueue_smallest (__rmqueue)
676 ls-4339 0d..2 5us : __mod_zone_page_state (__rmqueue_smallest)
677 ls-4339 0d..2 6us : __rmqueue (rmqueue_bulk)
678 ls-4339 0d..2 6us : __rmqueue_smallest (__rmqueue)
679 ls-4339 0d..2 7us : __mod_zone_page_state (__rmqueue_smallest)
680 ls-4339 0d..2 7us : __rmqueue (rmqueue_bulk)
681 ls-4339 0d..2 8us : __rmqueue_smallest (__rmqueue)
683 ls-4339 0d..2 46us : __rmqueue_smallest (__rmqueue)
684 ls-4339 0d..2 47us : __mod_zone_page_state (__rmqueue_smallest)
685 ls-4339 0d..2 47us : __rmqueue (rmqueue_bulk)
686 ls-4339 0d..2 48us : __rmqueue_smallest (__rmqueue)
687 ls-4339 0d..2 48us : __mod_zone_page_state (__rmqueue_smallest)
688 ls-4339 0d..2 49us : _spin_unlock (rmqueue_bulk)
689 ls-4339 0d..2 49us : sub_preempt_count (_spin_unlock)
690 ls-4339 0d..1 50us : get_page_from_freelist (__alloc_pages_internal)
691 ls-4339 0d..2 51us : trace_hardirqs_on (__alloc_pages_internal)
695 Here we traced a 50 microsecond latency. But we also see all the
696 functions that were called during that time. Note that by
697 enabling function tracing, we incur an added overhead. This
698 overhead may extend the latency times. But nevertheless, this
699 trace has provided some very helpful debugging information.
705 When preemption is disabled, we may be able to receive
706 interrupts but the task cannot be preempted and a higher
707 priority task must wait for preemption to be enabled again
708 before it can preempt a lower priority task.
710 The preemptoff tracer traces the places that disable preemption.
711 Like the irqsoff tracer, it records the maximum latency for
712 which preemption was disabled. The control of preemptoff tracer
713 is much like the irqsoff tracer.
715 # echo preemptoff > current_tracer
716 # echo latency-format > trace_options
717 # echo 0 > tracing_max_latency
718 # echo 1 > tracing_enabled
721 # echo 0 > tracing_enabled
725 preemptoff latency trace v1.1.5 on 2.6.26-rc8
726 --------------------------------------------------------------------
727 latency: 29 us, #3/3, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
729 | task: sshd-4261 (uid:0 nice:0 policy:0 rt_prio:0)
731 => started at: do_IRQ
732 => ended at: __do_softirq
735 # / _-----=> irqs-off
736 # | / _----=> need-resched
737 # || / _---=> hardirq/softirq
738 # ||| / _--=> preempt-depth
741 # cmd pid ||||| time | caller
743 sshd-4261 0d.h. 0us+: irq_enter (do_IRQ)
744 sshd-4261 0d.s. 29us : _local_bh_enable (__do_softirq)
745 sshd-4261 0d.s1 30us : trace_preempt_on (__do_softirq)
748 This has some more changes. Preemption was disabled when an
749 interrupt came in (notice the 'h'), and was enabled while doing
750 a softirq. (notice the 's'). But we also see that interrupts
751 have been disabled when entering the preempt off section and
752 leaving it (the 'd'). We do not know if interrupts were enabled
757 preemptoff latency trace v1.1.5 on 2.6.26-rc8
758 --------------------------------------------------------------------
759 latency: 63 us, #87/87, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
761 | task: sshd-4261 (uid:0 nice:0 policy:0 rt_prio:0)
763 => started at: remove_wait_queue
764 => ended at: __do_softirq
767 # / _-----=> irqs-off
768 # | / _----=> need-resched
769 # || / _---=> hardirq/softirq
770 # ||| / _--=> preempt-depth
773 # cmd pid ||||| time | caller
775 sshd-4261 0d..1 0us : _spin_lock_irqsave (remove_wait_queue)
776 sshd-4261 0d..1 1us : _spin_unlock_irqrestore (remove_wait_queue)
777 sshd-4261 0d..1 2us : do_IRQ (common_interrupt)
778 sshd-4261 0d..1 2us : irq_enter (do_IRQ)
779 sshd-4261 0d..1 2us : idle_cpu (irq_enter)
780 sshd-4261 0d..1 3us : add_preempt_count (irq_enter)
781 sshd-4261 0d.h1 3us : idle_cpu (irq_enter)
782 sshd-4261 0d.h. 4us : handle_fasteoi_irq (do_IRQ)
784 sshd-4261 0d.h. 12us : add_preempt_count (_spin_lock)
785 sshd-4261 0d.h1 12us : ack_ioapic_quirk_irq (handle_fasteoi_irq)
786 sshd-4261 0d.h1 13us : move_native_irq (ack_ioapic_quirk_irq)
787 sshd-4261 0d.h1 13us : _spin_unlock (handle_fasteoi_irq)
788 sshd-4261 0d.h1 14us : sub_preempt_count (_spin_unlock)
789 sshd-4261 0d.h1 14us : irq_exit (do_IRQ)
790 sshd-4261 0d.h1 15us : sub_preempt_count (irq_exit)
791 sshd-4261 0d..2 15us : do_softirq (irq_exit)
792 sshd-4261 0d... 15us : __do_softirq (do_softirq)
793 sshd-4261 0d... 16us : __local_bh_disable (__do_softirq)
794 sshd-4261 0d... 16us+: add_preempt_count (__local_bh_disable)
795 sshd-4261 0d.s4 20us : add_preempt_count (__local_bh_disable)
796 sshd-4261 0d.s4 21us : sub_preempt_count (local_bh_enable)
797 sshd-4261 0d.s5 21us : sub_preempt_count (local_bh_enable)
799 sshd-4261 0d.s6 41us : add_preempt_count (__local_bh_disable)
800 sshd-4261 0d.s6 42us : sub_preempt_count (local_bh_enable)
801 sshd-4261 0d.s7 42us : sub_preempt_count (local_bh_enable)
802 sshd-4261 0d.s5 43us : add_preempt_count (__local_bh_disable)
803 sshd-4261 0d.s5 43us : sub_preempt_count (local_bh_enable_ip)
804 sshd-4261 0d.s6 44us : sub_preempt_count (local_bh_enable_ip)
805 sshd-4261 0d.s5 44us : add_preempt_count (__local_bh_disable)
806 sshd-4261 0d.s5 45us : sub_preempt_count (local_bh_enable)
808 sshd-4261 0d.s. 63us : _local_bh_enable (__do_softirq)
809 sshd-4261 0d.s1 64us : trace_preempt_on (__do_softirq)
812 The above is an example of the preemptoff trace with
813 ftrace_enabled set. Here we see that interrupts were disabled
814 the entire time. The irq_enter code lets us know that we entered
815 an interrupt 'h'. Before that, the functions being traced still
816 show that it is not in an interrupt, but we can see from the
817 functions themselves that this is not the case.
819 Notice that __do_softirq when called does not have a
820 preempt_count. It may seem that we missed a preempt enabling.
821 What really happened is that the preempt count is held on the
822 thread's stack and we switched to the softirq stack (4K stacks
823 in effect). The code does not copy the preempt count, but
824 because interrupts are disabled, we do not need to worry about
825 it. Having a tracer like this is good for letting people know
826 what really happens inside the kernel.
832 Knowing the locations that have interrupts disabled or
833 preemption disabled for the longest times is helpful. But
834 sometimes we would like to know when either preemption and/or
835 interrupts are disabled.
837 Consider the following code:
840 call_function_with_irqs_off();
842 call_function_with_irqs_and_preemption_off();
844 call_function_with_preemption_off();
847 The irqsoff tracer will record the total length of
848 call_function_with_irqs_off() and
849 call_function_with_irqs_and_preemption_off().
851 The preemptoff tracer will record the total length of
852 call_function_with_irqs_and_preemption_off() and
853 call_function_with_preemption_off().
855 But neither will trace the time that interrupts and/or
856 preemption is disabled. This total time is the time that we can
857 not schedule. To record this time, use the preemptirqsoff
860 Again, using this trace is much like the irqsoff and preemptoff
863 # echo preemptirqsoff > current_tracer
864 # echo latency-format > trace_options
865 # echo 0 > tracing_max_latency
866 # echo 1 > tracing_enabled
869 # echo 0 > tracing_enabled
871 # tracer: preemptirqsoff
873 preemptirqsoff latency trace v1.1.5 on 2.6.26-rc8
874 --------------------------------------------------------------------
875 latency: 293 us, #3/3, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
877 | task: ls-4860 (uid:0 nice:0 policy:0 rt_prio:0)
879 => started at: apic_timer_interrupt
880 => ended at: __do_softirq
883 # / _-----=> irqs-off
884 # | / _----=> need-resched
885 # || / _---=> hardirq/softirq
886 # ||| / _--=> preempt-depth
889 # cmd pid ||||| time | caller
891 ls-4860 0d... 0us!: trace_hardirqs_off_thunk (apic_timer_interrupt)
892 ls-4860 0d.s. 294us : _local_bh_enable (__do_softirq)
893 ls-4860 0d.s1 294us : trace_preempt_on (__do_softirq)
897 The trace_hardirqs_off_thunk is called from assembly on x86 when
898 interrupts are disabled in the assembly code. Without the
899 function tracing, we do not know if interrupts were enabled
900 within the preemption points. We do see that it started with
903 Here is a trace with ftrace_enabled set:
906 # tracer: preemptirqsoff
908 preemptirqsoff latency trace v1.1.5 on 2.6.26-rc8
909 --------------------------------------------------------------------
910 latency: 105 us, #183/183, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
912 | task: sshd-4261 (uid:0 nice:0 policy:0 rt_prio:0)
914 => started at: write_chan
915 => ended at: __do_softirq
918 # / _-----=> irqs-off
919 # | / _----=> need-resched
920 # || / _---=> hardirq/softirq
921 # ||| / _--=> preempt-depth
924 # cmd pid ||||| time | caller
926 ls-4473 0.N.. 0us : preempt_schedule (write_chan)
927 ls-4473 0dN.1 1us : _spin_lock (schedule)
928 ls-4473 0dN.1 2us : add_preempt_count (_spin_lock)
929 ls-4473 0d..2 2us : put_prev_task_fair (schedule)
931 ls-4473 0d..2 13us : set_normalized_timespec (ktime_get_ts)
932 ls-4473 0d..2 13us : __switch_to (schedule)
933 sshd-4261 0d..2 14us : finish_task_switch (schedule)
934 sshd-4261 0d..2 14us : _spin_unlock_irq (finish_task_switch)
935 sshd-4261 0d..1 15us : add_preempt_count (_spin_lock_irqsave)
936 sshd-4261 0d..2 16us : _spin_unlock_irqrestore (hrtick_set)
937 sshd-4261 0d..2 16us : do_IRQ (common_interrupt)
938 sshd-4261 0d..2 17us : irq_enter (do_IRQ)
939 sshd-4261 0d..2 17us : idle_cpu (irq_enter)
940 sshd-4261 0d..2 18us : add_preempt_count (irq_enter)
941 sshd-4261 0d.h2 18us : idle_cpu (irq_enter)
942 sshd-4261 0d.h. 18us : handle_fasteoi_irq (do_IRQ)
943 sshd-4261 0d.h. 19us : _spin_lock (handle_fasteoi_irq)
944 sshd-4261 0d.h. 19us : add_preempt_count (_spin_lock)
945 sshd-4261 0d.h1 20us : _spin_unlock (handle_fasteoi_irq)
946 sshd-4261 0d.h1 20us : sub_preempt_count (_spin_unlock)
948 sshd-4261 0d.h1 28us : _spin_unlock (handle_fasteoi_irq)
949 sshd-4261 0d.h1 29us : sub_preempt_count (_spin_unlock)
950 sshd-4261 0d.h2 29us : irq_exit (do_IRQ)
951 sshd-4261 0d.h2 29us : sub_preempt_count (irq_exit)
952 sshd-4261 0d..3 30us : do_softirq (irq_exit)
953 sshd-4261 0d... 30us : __do_softirq (do_softirq)
954 sshd-4261 0d... 31us : __local_bh_disable (__do_softirq)
955 sshd-4261 0d... 31us+: add_preempt_count (__local_bh_disable)
956 sshd-4261 0d.s4 34us : add_preempt_count (__local_bh_disable)
958 sshd-4261 0d.s3 43us : sub_preempt_count (local_bh_enable_ip)
959 sshd-4261 0d.s4 44us : sub_preempt_count (local_bh_enable_ip)
960 sshd-4261 0d.s3 44us : smp_apic_timer_interrupt (apic_timer_interrupt)
961 sshd-4261 0d.s3 45us : irq_enter (smp_apic_timer_interrupt)
962 sshd-4261 0d.s3 45us : idle_cpu (irq_enter)
963 sshd-4261 0d.s3 46us : add_preempt_count (irq_enter)
964 sshd-4261 0d.H3 46us : idle_cpu (irq_enter)
965 sshd-4261 0d.H3 47us : hrtimer_interrupt (smp_apic_timer_interrupt)
966 sshd-4261 0d.H3 47us : ktime_get (hrtimer_interrupt)
968 sshd-4261 0d.H3 81us : tick_program_event (hrtimer_interrupt)
969 sshd-4261 0d.H3 82us : ktime_get (tick_program_event)
970 sshd-4261 0d.H3 82us : ktime_get_ts (ktime_get)
971 sshd-4261 0d.H3 83us : getnstimeofday (ktime_get_ts)
972 sshd-4261 0d.H3 83us : set_normalized_timespec (ktime_get_ts)
973 sshd-4261 0d.H3 84us : clockevents_program_event (tick_program_event)
974 sshd-4261 0d.H3 84us : lapic_next_event (clockevents_program_event)
975 sshd-4261 0d.H3 85us : irq_exit (smp_apic_timer_interrupt)
976 sshd-4261 0d.H3 85us : sub_preempt_count (irq_exit)
977 sshd-4261 0d.s4 86us : sub_preempt_count (irq_exit)
978 sshd-4261 0d.s3 86us : add_preempt_count (__local_bh_disable)
980 sshd-4261 0d.s1 98us : sub_preempt_count (net_rx_action)
981 sshd-4261 0d.s. 99us : add_preempt_count (_spin_lock_irq)
982 sshd-4261 0d.s1 99us+: _spin_unlock_irq (run_timer_softirq)
983 sshd-4261 0d.s. 104us : _local_bh_enable (__do_softirq)
984 sshd-4261 0d.s. 104us : sub_preempt_count (_local_bh_enable)
985 sshd-4261 0d.s. 105us : _local_bh_enable (__do_softirq)
986 sshd-4261 0d.s1 105us : trace_preempt_on (__do_softirq)
989 This is a very interesting trace. It started with the preemption
990 of the ls task. We see that the task had the "need_resched" bit
991 set via the 'N' in the trace. Interrupts were disabled before
992 the spin_lock at the beginning of the trace. We see that a
993 schedule took place to run sshd. When the interrupts were
994 enabled, we took an interrupt. On return from the interrupt
995 handler, the softirq ran. We took another interrupt while
996 running the softirq as we see from the capital 'H'.
1002 In a Real-Time environment it is very important to know the
1003 wakeup time it takes for the highest priority task that is woken
1004 up to the time that it executes. This is also known as "schedule
1005 latency". I stress the point that this is about RT tasks. It is
1006 also important to know the scheduling latency of non-RT tasks,
1007 but the average schedule latency is better for non-RT tasks.
1008 Tools like LatencyTop are more appropriate for such
1011 Real-Time environments are interested in the worst case latency.
1012 That is the longest latency it takes for something to happen,
1013 and not the average. We can have a very fast scheduler that may
1014 only have a large latency once in a while, but that would not
1015 work well with Real-Time tasks. The wakeup tracer was designed
1016 to record the worst case wakeups of RT tasks. Non-RT tasks are
1017 not recorded because the tracer only records one worst case and
1018 tracing non-RT tasks that are unpredictable will overwrite the
1019 worst case latency of RT tasks.
1021 Since this tracer only deals with RT tasks, we will run this
1022 slightly differently than we did with the previous tracers.
1023 Instead of performing an 'ls', we will run 'sleep 1' under
1024 'chrt' which changes the priority of the task.
1026 # echo wakeup > current_tracer
1027 # echo latency-format > trace_options
1028 # echo 0 > tracing_max_latency
1029 # echo 1 > tracing_enabled
1031 # echo 0 > tracing_enabled
1035 wakeup latency trace v1.1.5 on 2.6.26-rc8
1036 --------------------------------------------------------------------
1037 latency: 4 us, #2/2, CPU#1 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
1039 | task: sleep-4901 (uid:0 nice:0 policy:1 rt_prio:5)
1043 # / _-----=> irqs-off
1044 # | / _----=> need-resched
1045 # || / _---=> hardirq/softirq
1046 # ||| / _--=> preempt-depth
1049 # cmd pid ||||| time | caller
1051 <idle>-0 1d.h4 0us+: try_to_wake_up (wake_up_process)
1052 <idle>-0 1d..4 4us : schedule (cpu_idle)
1055 Running this on an idle system, we see that it only took 4
1056 microseconds to perform the task switch. Note, since the trace
1057 marker in the schedule is before the actual "switch", we stop
1058 the tracing when the recorded task is about to schedule in. This
1059 may change if we add a new marker at the end of the scheduler.
1061 Notice that the recorded task is 'sleep' with the PID of 4901
1062 and it has an rt_prio of 5. This priority is user-space priority
1063 and not the internal kernel priority. The policy is 1 for
1064 SCHED_FIFO and 2 for SCHED_RR.
1066 Doing the same with chrt -r 5 and ftrace_enabled set.
1070 wakeup latency trace v1.1.5 on 2.6.26-rc8
1071 --------------------------------------------------------------------
1072 latency: 50 us, #60/60, CPU#1 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:2)
1074 | task: sleep-4068 (uid:0 nice:0 policy:2 rt_prio:5)
1078 # / _-----=> irqs-off
1079 # | / _----=> need-resched
1080 # || / _---=> hardirq/softirq
1081 # ||| / _--=> preempt-depth
1084 # cmd pid ||||| time | caller
1086 ksoftirq-7 1d.H3 0us : try_to_wake_up (wake_up_process)
1087 ksoftirq-7 1d.H4 1us : sub_preempt_count (marker_probe_cb)
1088 ksoftirq-7 1d.H3 2us : check_preempt_wakeup (try_to_wake_up)
1089 ksoftirq-7 1d.H3 3us : update_curr (check_preempt_wakeup)
1090 ksoftirq-7 1d.H3 4us : calc_delta_mine (update_curr)
1091 ksoftirq-7 1d.H3 5us : __resched_task (check_preempt_wakeup)
1092 ksoftirq-7 1d.H3 6us : task_wake_up_rt (try_to_wake_up)
1093 ksoftirq-7 1d.H3 7us : _spin_unlock_irqrestore (try_to_wake_up)
1095 ksoftirq-7 1d.H2 17us : irq_exit (smp_apic_timer_interrupt)
1096 ksoftirq-7 1d.H2 18us : sub_preempt_count (irq_exit)
1097 ksoftirq-7 1d.s3 19us : sub_preempt_count (irq_exit)
1098 ksoftirq-7 1..s2 20us : rcu_process_callbacks (__do_softirq)
1100 ksoftirq-7 1..s2 26us : __rcu_process_callbacks (rcu_process_callbacks)
1101 ksoftirq-7 1d.s2 27us : _local_bh_enable (__do_softirq)
1102 ksoftirq-7 1d.s2 28us : sub_preempt_count (_local_bh_enable)
1103 ksoftirq-7 1.N.3 29us : sub_preempt_count (ksoftirqd)
1104 ksoftirq-7 1.N.2 30us : _cond_resched (ksoftirqd)
1105 ksoftirq-7 1.N.2 31us : __cond_resched (_cond_resched)
1106 ksoftirq-7 1.N.2 32us : add_preempt_count (__cond_resched)
1107 ksoftirq-7 1.N.2 33us : schedule (__cond_resched)
1108 ksoftirq-7 1.N.2 33us : add_preempt_count (schedule)
1109 ksoftirq-7 1.N.3 34us : hrtick_clear (schedule)
1110 ksoftirq-7 1dN.3 35us : _spin_lock (schedule)
1111 ksoftirq-7 1dN.3 36us : add_preempt_count (_spin_lock)
1112 ksoftirq-7 1d..4 37us : put_prev_task_fair (schedule)
1113 ksoftirq-7 1d..4 38us : update_curr (put_prev_task_fair)
1115 ksoftirq-7 1d..5 47us : _spin_trylock (tracing_record_cmdline)
1116 ksoftirq-7 1d..5 48us : add_preempt_count (_spin_trylock)
1117 ksoftirq-7 1d..6 49us : _spin_unlock (tracing_record_cmdline)
1118 ksoftirq-7 1d..6 49us : sub_preempt_count (_spin_unlock)
1119 ksoftirq-7 1d..4 50us : schedule (__cond_resched)
1121 The interrupt went off while running ksoftirqd. This task runs
1122 at SCHED_OTHER. Why did not we see the 'N' set early? This may
1123 be a harmless bug with x86_32 and 4K stacks. On x86_32 with 4K
1124 stacks configured, the interrupt and softirq run with their own
1125 stack. Some information is held on the top of the task's stack
1126 (need_resched and preempt_count are both stored there). The
1127 setting of the NEED_RESCHED bit is done directly to the task's
1128 stack, but the reading of the NEED_RESCHED is done by looking at
1129 the current stack, which in this case is the stack for the hard
1130 interrupt. This hides the fact that NEED_RESCHED has been set.
1131 We do not see the 'N' until we switch back to the task's
1137 This tracer is the function tracer. Enabling the function tracer
1138 can be done from the debug file system. Make sure the
1139 ftrace_enabled is set; otherwise this tracer is a nop.
1141 # sysctl kernel.ftrace_enabled=1
1142 # echo function > current_tracer
1143 # echo 1 > tracing_enabled
1145 # echo 0 > tracing_enabled
1149 # TASK-PID CPU# TIMESTAMP FUNCTION
1151 bash-4003 [00] 123.638713: finish_task_switch <-schedule
1152 bash-4003 [00] 123.638714: _spin_unlock_irq <-finish_task_switch
1153 bash-4003 [00] 123.638714: sub_preempt_count <-_spin_unlock_irq
1154 bash-4003 [00] 123.638715: hrtick_set <-schedule
1155 bash-4003 [00] 123.638715: _spin_lock_irqsave <-hrtick_set
1156 bash-4003 [00] 123.638716: add_preempt_count <-_spin_lock_irqsave
1157 bash-4003 [00] 123.638716: _spin_unlock_irqrestore <-hrtick_set
1158 bash-4003 [00] 123.638717: sub_preempt_count <-_spin_unlock_irqrestore
1159 bash-4003 [00] 123.638717: hrtick_clear <-hrtick_set
1160 bash-4003 [00] 123.638718: sub_preempt_count <-schedule
1161 bash-4003 [00] 123.638718: sub_preempt_count <-preempt_schedule
1162 bash-4003 [00] 123.638719: wait_for_completion <-__stop_machine_run
1163 bash-4003 [00] 123.638719: wait_for_common <-wait_for_completion
1164 bash-4003 [00] 123.638720: _spin_lock_irq <-wait_for_common
1165 bash-4003 [00] 123.638720: add_preempt_count <-_spin_lock_irq
1169 Note: function tracer uses ring buffers to store the above
1170 entries. The newest data may overwrite the oldest data.
1171 Sometimes using echo to stop the trace is not sufficient because
1172 the tracing could have overwritten the data that you wanted to
1173 record. For this reason, it is sometimes better to disable
1174 tracing directly from a program. This allows you to stop the
1175 tracing at the point that you hit the part that you are
1176 interested in. To disable the tracing directly from a C program,
1177 something like following code snippet can be used:
1181 int main(int argc, char *argv[]) {
1183 trace_fd = open(tracing_file("tracing_enabled"), O_WRONLY);
1185 if (condition_hit()) {
1186 write(trace_fd, "0", 1);
1192 Single thread tracing
1193 ---------------------
1195 By writing into set_ftrace_pid you can trace a
1196 single thread. For example:
1198 # cat set_ftrace_pid
1200 # echo 3111 > set_ftrace_pid
1201 # cat set_ftrace_pid
1203 # echo function > current_tracer
1207 # TASK-PID CPU# TIMESTAMP FUNCTION
1209 yum-updatesd-3111 [003] 1637.254676: finish_task_switch <-thread_return
1210 yum-updatesd-3111 [003] 1637.254681: hrtimer_cancel <-schedule_hrtimeout_range
1211 yum-updatesd-3111 [003] 1637.254682: hrtimer_try_to_cancel <-hrtimer_cancel
1212 yum-updatesd-3111 [003] 1637.254683: lock_hrtimer_base <-hrtimer_try_to_cancel
1213 yum-updatesd-3111 [003] 1637.254685: fget_light <-do_sys_poll
1214 yum-updatesd-3111 [003] 1637.254686: pipe_poll <-do_sys_poll
1215 # echo -1 > set_ftrace_pid
1219 # TASK-PID CPU# TIMESTAMP FUNCTION
1221 ##### CPU 3 buffer started ####
1222 yum-updatesd-3111 [003] 1701.957688: free_poll_entry <-poll_freewait
1223 yum-updatesd-3111 [003] 1701.957689: remove_wait_queue <-free_poll_entry
1224 yum-updatesd-3111 [003] 1701.957691: fput <-free_poll_entry
1225 yum-updatesd-3111 [003] 1701.957692: audit_syscall_exit <-sysret_audit
1226 yum-updatesd-3111 [003] 1701.957693: path_put <-audit_syscall_exit
1228 If you want to trace a function when executing, you could use
1229 something like this simple program:
1233 #include <sys/types.h>
1234 #include <sys/stat.h>
1240 #define STR(x) _STR(x)
1241 #define MAX_PATH 256
1243 const char *find_debugfs(void)
1245 static char debugfs[MAX_PATH+1];
1246 static int debugfs_found;
1253 if ((fp = fopen("/proc/mounts","r")) == NULL) {
1254 perror("/proc/mounts");
1258 while (fscanf(fp, "%*s %"
1260 "s %99s %*s %*d %*d\n",
1261 debugfs, type) == 2) {
1262 if (strcmp(type, "debugfs") == 0)
1267 if (strcmp(type, "debugfs") != 0) {
1268 fprintf(stderr, "debugfs not mounted");
1272 strcat(debugfs, "/tracing/");
1278 const char *tracing_file(const char *file_name)
1280 static char trace_file[MAX_PATH+1];
1281 snprintf(trace_file, MAX_PATH, "%s/%s", find_debugfs(), file_name);
1285 int main (int argc, char **argv)
1295 ffd = open(tracing_file("current_tracer"), O_WRONLY);
1298 write(ffd, "nop", 3);
1300 fd = open(tracing_file("set_ftrace_pid"), O_WRONLY);
1301 s = sprintf(line, "%d\n", getpid());
1304 write(ffd, "function", 8);
1309 execvp(argv[1], argv+1);
1316 hw-branch-tracer (x86 only)
1317 ---------------------------
1319 This tracer uses the x86 last branch tracing hardware feature to
1320 collect a branch trace on all cpus with relatively low overhead.
1322 The tracer uses a fixed-size circular buffer per cpu and only
1323 traces ring 0 branches. The trace file dumps that buffer in the
1326 # tracer: hw-branch-tracer
1329 0 scheduler_tick+0xb5/0x1bf <- task_tick_idle+0x5/0x6
1330 2 run_posix_cpu_timers+0x2b/0x72a <- run_posix_cpu_timers+0x25/0x72a
1331 0 scheduler_tick+0x139/0x1bf <- scheduler_tick+0xed/0x1bf
1332 0 scheduler_tick+0x17c/0x1bf <- scheduler_tick+0x148/0x1bf
1333 2 run_posix_cpu_timers+0x9e/0x72a <- run_posix_cpu_timers+0x5e/0x72a
1334 0 scheduler_tick+0x1b6/0x1bf <- scheduler_tick+0x1aa/0x1bf
1337 The tracer may be used to dump the trace for the oops'ing cpu on
1338 a kernel oops into the system log. To enable this,
1339 ftrace_dump_on_oops must be set. To set ftrace_dump_on_oops, one
1340 can either use the sysctl function or set it via the proc system
1343 sysctl kernel.ftrace_dump_on_oops=n
1347 echo n > /proc/sys/kernel/ftrace_dump_on_oops
1349 If n = 1, ftrace will dump buffers of all CPUs, if n = 2 ftrace will
1350 only dump the buffer of the CPU that triggered the oops.
1352 Here's an example of such a dump after a null pointer
1353 dereference in a kernel module:
1355 [57848.105921] BUG: unable to handle kernel NULL pointer dereference at 0000000000000000
1356 [57848.106019] IP: [<ffffffffa0000006>] open+0x6/0x14 [oops]
1357 [57848.106019] PGD 2354e9067 PUD 2375e7067 PMD 0
1358 [57848.106019] Oops: 0002 [#1] SMP
1359 [57848.106019] last sysfs file: /sys/devices/pci0000:00/0000:00:1e.0/0000:20:05.0/local_cpus
1360 [57848.106019] Dumping ftrace buffer:
1361 [57848.106019] ---------------------------------
1363 [57848.106019] 0 chrdev_open+0xe6/0x165 <- cdev_put+0x23/0x24
1364 [57848.106019] 0 chrdev_open+0x117/0x165 <- chrdev_open+0xfa/0x165
1365 [57848.106019] 0 chrdev_open+0x120/0x165 <- chrdev_open+0x11c/0x165
1366 [57848.106019] 0 chrdev_open+0x134/0x165 <- chrdev_open+0x12b/0x165
1367 [57848.106019] 0 open+0x0/0x14 [oops] <- chrdev_open+0x144/0x165
1368 [57848.106019] 0 page_fault+0x0/0x30 <- open+0x6/0x14 [oops]
1369 [57848.106019] 0 error_entry+0x0/0x5b <- page_fault+0x4/0x30
1370 [57848.106019] 0 error_kernelspace+0x0/0x31 <- error_entry+0x59/0x5b
1371 [57848.106019] 0 error_sti+0x0/0x1 <- error_kernelspace+0x2d/0x31
1372 [57848.106019] 0 page_fault+0x9/0x30 <- error_sti+0x0/0x1
1373 [57848.106019] 0 do_page_fault+0x0/0x881 <- page_fault+0x1a/0x30
1375 [57848.106019] 0 do_page_fault+0x66b/0x881 <- is_prefetch+0x1ee/0x1f2
1376 [57848.106019] 0 do_page_fault+0x6e0/0x881 <- do_page_fault+0x67a/0x881
1377 [57848.106019] 0 oops_begin+0x0/0x96 <- do_page_fault+0x6e0/0x881
1378 [57848.106019] 0 trace_hw_branch_oops+0x0/0x2d <- oops_begin+0x9/0x96
1380 [57848.106019] 0 ds_suspend_bts+0x2a/0xe3 <- ds_suspend_bts+0x1a/0xe3
1381 [57848.106019] ---------------------------------
1382 [57848.106019] CPU 0
1383 [57848.106019] Modules linked in: oops
1384 [57848.106019] Pid: 5542, comm: cat Tainted: G W 2.6.28 #23
1385 [57848.106019] RIP: 0010:[<ffffffffa0000006>] [<ffffffffa0000006>] open+0x6/0x14 [oops]
1386 [57848.106019] RSP: 0018:ffff880235457d48 EFLAGS: 00010246
1390 function graph tracer
1391 ---------------------------
1393 This tracer is similar to the function tracer except that it
1394 probes a function on its entry and its exit. This is done by
1395 using a dynamically allocated stack of return addresses in each
1396 task_struct. On function entry the tracer overwrites the return
1397 address of each function traced to set a custom probe. Thus the
1398 original return address is stored on the stack of return address
1401 Probing on both ends of a function leads to special features
1404 - measure of a function's time execution
1405 - having a reliable call stack to draw function calls graph
1407 This tracer is useful in several situations:
1409 - you want to find the reason of a strange kernel behavior and
1410 need to see what happens in detail on any areas (or specific
1413 - you are experiencing weird latencies but it's difficult to
1416 - you want to find quickly which path is taken by a specific
1419 - you just want to peek inside a working kernel and want to see
1422 # tracer: function_graph
1424 # CPU DURATION FUNCTION CALLS
1428 0) | do_sys_open() {
1430 0) | kmem_cache_alloc() {
1431 0) 1.382 us | __might_sleep();
1433 0) | strncpy_from_user() {
1434 0) | might_fault() {
1435 0) 1.389 us | __might_sleep();
1440 0) 0.668 us | _spin_lock();
1441 0) 0.570 us | expand_files();
1442 0) 0.586 us | _spin_unlock();
1445 There are several columns that can be dynamically
1446 enabled/disabled. You can use every combination of options you
1447 want, depending on your needs.
1449 - The cpu number on which the function executed is default
1450 enabled. It is sometimes better to only trace one cpu (see
1451 tracing_cpu_mask file) or you might sometimes see unordered
1452 function calls while cpu tracing switch.
1454 hide: echo nofuncgraph-cpu > trace_options
1455 show: echo funcgraph-cpu > trace_options
1457 - The duration (function's time of execution) is displayed on
1458 the closing bracket line of a function or on the same line
1459 than the current function in case of a leaf one. It is default
1462 hide: echo nofuncgraph-duration > trace_options
1463 show: echo funcgraph-duration > trace_options
1465 - The overhead field precedes the duration field in case of
1466 reached duration thresholds.
1468 hide: echo nofuncgraph-overhead > trace_options
1469 show: echo funcgraph-overhead > trace_options
1470 depends on: funcgraph-duration
1475 0) 0.646 us | _spin_lock_irqsave();
1476 0) 0.684 us | _spin_unlock_irqrestore();
1478 0) 0.548 us | fput();
1484 0) | kmem_cache_free() {
1485 0) 0.518 us | __phys_addr();
1491 + means that the function exceeded 10 usecs.
1492 ! means that the function exceeded 100 usecs.
1495 - The task/pid field displays the thread cmdline and pid which
1496 executed the function. It is default disabled.
1498 hide: echo nofuncgraph-proc > trace_options
1499 show: echo funcgraph-proc > trace_options
1503 # tracer: function_graph
1505 # CPU TASK/PID DURATION FUNCTION CALLS
1507 0) sh-4802 | | d_free() {
1508 0) sh-4802 | | call_rcu() {
1509 0) sh-4802 | | __call_rcu() {
1510 0) sh-4802 | 0.616 us | rcu_process_gp_end();
1511 0) sh-4802 | 0.586 us | check_for_new_grace_period();
1512 0) sh-4802 | 2.899 us | }
1513 0) sh-4802 | 4.040 us | }
1514 0) sh-4802 | 5.151 us | }
1515 0) sh-4802 | + 49.370 us | }
1518 - The absolute time field is an absolute timestamp given by the
1519 system clock since it started. A snapshot of this time is
1520 given on each entry/exit of functions
1522 hide: echo nofuncgraph-abstime > trace_options
1523 show: echo funcgraph-abstime > trace_options
1528 # TIME CPU DURATION FUNCTION CALLS
1530 360.774522 | 1) 0.541 us | }
1531 360.774522 | 1) 4.663 us | }
1532 360.774523 | 1) 0.541 us | __wake_up_bit();
1533 360.774524 | 1) 6.796 us | }
1534 360.774524 | 1) 7.952 us | }
1535 360.774525 | 1) 9.063 us | }
1536 360.774525 | 1) 0.615 us | journal_mark_dirty();
1537 360.774527 | 1) 0.578 us | __brelse();
1538 360.774528 | 1) | reiserfs_prepare_for_journal() {
1539 360.774528 | 1) | unlock_buffer() {
1540 360.774529 | 1) | wake_up_bit() {
1541 360.774529 | 1) | bit_waitqueue() {
1542 360.774530 | 1) 0.594 us | __phys_addr();
1545 You can put some comments on specific functions by using
1546 trace_printk() For example, if you want to put a comment inside
1547 the __might_sleep() function, you just have to include
1548 <linux/ftrace.h> and call trace_printk() inside __might_sleep()
1550 trace_printk("I'm a comment!\n")
1554 1) | __might_sleep() {
1555 1) | /* I'm a comment! */
1559 You might find other useful features for this tracer in the
1560 following "dynamic ftrace" section such as tracing only specific
1566 If CONFIG_DYNAMIC_FTRACE is set, the system will run with
1567 virtually no overhead when function tracing is disabled. The way
1568 this works is the mcount function call (placed at the start of
1569 every kernel function, produced by the -pg switch in gcc),
1570 starts of pointing to a simple return. (Enabling FTRACE will
1571 include the -pg switch in the compiling of the kernel.)
1573 At compile time every C file object is run through the
1574 recordmcount.pl script (located in the scripts directory). This
1575 script will process the C object using objdump to find all the
1576 locations in the .text section that call mcount. (Note, only the
1577 .text section is processed, since processing other sections like
1578 .init.text may cause races due to those sections being freed).
1580 A new section called "__mcount_loc" is created that holds
1581 references to all the mcount call sites in the .text section.
1582 This section is compiled back into the original object. The
1583 final linker will add all these references into a single table.
1585 On boot up, before SMP is initialized, the dynamic ftrace code
1586 scans this table and updates all the locations into nops. It
1587 also records the locations, which are added to the
1588 available_filter_functions list. Modules are processed as they
1589 are loaded and before they are executed. When a module is
1590 unloaded, it also removes its functions from the ftrace function
1591 list. This is automatic in the module unload code, and the
1592 module author does not need to worry about it.
1594 When tracing is enabled, kstop_machine is called to prevent
1595 races with the CPUS executing code being modified (which can
1596 cause the CPU to do undesirable things), and the nops are
1597 patched back to calls. But this time, they do not call mcount
1598 (which is just a function stub). They now call into the ftrace
1601 One special side-effect to the recording of the functions being
1602 traced is that we can now selectively choose which functions we
1603 wish to trace and which ones we want the mcount calls to remain
1606 Two files are used, one for enabling and one for disabling the
1607 tracing of specified functions. They are:
1615 A list of available functions that you can add to these files is
1618 available_filter_functions
1620 # cat available_filter_functions
1629 If I am only interested in sys_nanosleep and hrtimer_interrupt:
1631 # echo sys_nanosleep hrtimer_interrupt \
1633 # echo function > current_tracer
1634 # echo 1 > tracing_enabled
1636 # echo 0 > tracing_enabled
1640 # TASK-PID CPU# TIMESTAMP FUNCTION
1642 usleep-4134 [00] 1317.070017: hrtimer_interrupt <-smp_apic_timer_interrupt
1643 usleep-4134 [00] 1317.070111: sys_nanosleep <-syscall_call
1644 <idle>-0 [00] 1317.070115: hrtimer_interrupt <-smp_apic_timer_interrupt
1646 To see which functions are being traced, you can cat the file:
1648 # cat set_ftrace_filter
1653 Perhaps this is not enough. The filters also allow simple wild
1654 cards. Only the following are currently available
1656 <match>* - will match functions that begin with <match>
1657 *<match> - will match functions that end with <match>
1658 *<match>* - will match functions that have <match> in it
1660 These are the only wild cards which are supported.
1662 <match>*<match> will not work.
1664 Note: It is better to use quotes to enclose the wild cards,
1665 otherwise the shell may expand the parameters into names
1666 of files in the local directory.
1668 # echo 'hrtimer_*' > set_ftrace_filter
1674 # TASK-PID CPU# TIMESTAMP FUNCTION
1676 bash-4003 [00] 1480.611794: hrtimer_init <-copy_process
1677 bash-4003 [00] 1480.611941: hrtimer_start <-hrtick_set
1678 bash-4003 [00] 1480.611956: hrtimer_cancel <-hrtick_clear
1679 bash-4003 [00] 1480.611956: hrtimer_try_to_cancel <-hrtimer_cancel
1680 <idle>-0 [00] 1480.612019: hrtimer_get_next_event <-get_next_timer_interrupt
1681 <idle>-0 [00] 1480.612025: hrtimer_get_next_event <-get_next_timer_interrupt
1682 <idle>-0 [00] 1480.612032: hrtimer_get_next_event <-get_next_timer_interrupt
1683 <idle>-0 [00] 1480.612037: hrtimer_get_next_event <-get_next_timer_interrupt
1684 <idle>-0 [00] 1480.612382: hrtimer_get_next_event <-get_next_timer_interrupt
1687 Notice that we lost the sys_nanosleep.
1689 # cat set_ftrace_filter
1694 hrtimer_try_to_cancel
1698 hrtimer_force_reprogram
1699 hrtimer_get_next_event
1703 hrtimer_get_remaining
1705 hrtimer_init_sleeper
1708 This is because the '>' and '>>' act just like they do in bash.
1709 To rewrite the filters, use '>'
1710 To append to the filters, use '>>'
1712 To clear out a filter so that all functions will be recorded
1715 # echo > set_ftrace_filter
1716 # cat set_ftrace_filter
1719 Again, now we want to append.
1721 # echo sys_nanosleep > set_ftrace_filter
1722 # cat set_ftrace_filter
1724 # echo 'hrtimer_*' >> set_ftrace_filter
1725 # cat set_ftrace_filter
1730 hrtimer_try_to_cancel
1734 hrtimer_force_reprogram
1735 hrtimer_get_next_event
1740 hrtimer_get_remaining
1742 hrtimer_init_sleeper
1745 The set_ftrace_notrace prevents those functions from being
1748 # echo '*preempt*' '*lock*' > set_ftrace_notrace
1754 # TASK-PID CPU# TIMESTAMP FUNCTION
1756 bash-4043 [01] 115.281644: finish_task_switch <-schedule
1757 bash-4043 [01] 115.281645: hrtick_set <-schedule
1758 bash-4043 [01] 115.281645: hrtick_clear <-hrtick_set
1759 bash-4043 [01] 115.281646: wait_for_completion <-__stop_machine_run
1760 bash-4043 [01] 115.281647: wait_for_common <-wait_for_completion
1761 bash-4043 [01] 115.281647: kthread_stop <-stop_machine_run
1762 bash-4043 [01] 115.281648: init_waitqueue_head <-kthread_stop
1763 bash-4043 [01] 115.281648: wake_up_process <-kthread_stop
1764 bash-4043 [01] 115.281649: try_to_wake_up <-wake_up_process
1766 We can see that there's no more lock or preempt tracing.
1769 Dynamic ftrace with the function graph tracer
1770 ---------------------------------------------
1772 Although what has been explained above concerns both the
1773 function tracer and the function-graph-tracer, there are some
1774 special features only available in the function-graph tracer.
1776 If you want to trace only one function and all of its children,
1777 you just have to echo its name into set_graph_function:
1779 echo __do_fault > set_graph_function
1781 will produce the following "expanded" trace of the __do_fault()
1785 0) | filemap_fault() {
1786 0) | find_lock_page() {
1787 0) 0.804 us | find_get_page();
1788 0) | __might_sleep() {
1792 0) 0.653 us | _spin_lock();
1793 0) 0.578 us | page_add_file_rmap();
1794 0) 0.525 us | native_set_pte_at();
1795 0) 0.585 us | _spin_unlock();
1796 0) | unlock_page() {
1797 0) 0.541 us | page_waitqueue();
1798 0) 0.639 us | __wake_up_bit();
1802 0) | filemap_fault() {
1803 0) | find_lock_page() {
1804 0) 0.698 us | find_get_page();
1805 0) | __might_sleep() {
1809 0) 0.631 us | _spin_lock();
1810 0) 0.571 us | page_add_file_rmap();
1811 0) 0.526 us | native_set_pte_at();
1812 0) 0.586 us | _spin_unlock();
1813 0) | unlock_page() {
1814 0) 0.533 us | page_waitqueue();
1815 0) 0.638 us | __wake_up_bit();
1819 You can also expand several functions at once:
1821 echo sys_open > set_graph_function
1822 echo sys_close >> set_graph_function
1824 Now if you want to go back to trace all functions you can clear
1825 this special filter via:
1827 echo > set_graph_function
1833 A few commands are supported by the set_ftrace_filter interface.
1834 Trace commands have the following format:
1836 <function>:<command>:<parameter>
1838 The following commands are supported:
1841 This command enables function filtering per module. The
1842 parameter defines the module. For example, if only the write*
1843 functions in the ext3 module are desired, run:
1845 echo 'write*:mod:ext3' > set_ftrace_filter
1847 This command interacts with the filter in the same way as
1848 filtering based on function names. Thus, adding more functions
1849 in a different module is accomplished by appending (>>) to the
1850 filter file. Remove specific module functions by prepending
1853 echo '!writeback*:mod:ext3' >> set_ftrace_filter
1856 These commands turn tracing on and off when the specified
1857 functions are hit. The parameter determines how many times the
1858 tracing system is turned on and off. If unspecified, there is
1859 no limit. For example, to disable tracing when a schedule bug
1860 is hit the first 5 times, run:
1862 echo '__schedule_bug:traceoff:5' > set_ftrace_filter
1864 These commands are cumulative whether or not they are appended
1865 to set_ftrace_filter. To remove a command, prepend it by '!'
1866 and drop the parameter:
1868 echo '!__schedule_bug:traceoff' > set_ftrace_filter
1874 The trace_pipe outputs the same content as the trace file, but
1875 the effect on the tracing is different. Every read from
1876 trace_pipe is consumed. This means that subsequent reads will be
1877 different. The trace is live.
1879 # echo function > current_tracer
1880 # cat trace_pipe > /tmp/trace.out &
1882 # echo 1 > tracing_enabled
1884 # echo 0 > tracing_enabled
1888 # TASK-PID CPU# TIMESTAMP FUNCTION
1892 # cat /tmp/trace.out
1893 bash-4043 [00] 41.267106: finish_task_switch <-schedule
1894 bash-4043 [00] 41.267106: hrtick_set <-schedule
1895 bash-4043 [00] 41.267107: hrtick_clear <-hrtick_set
1896 bash-4043 [00] 41.267108: wait_for_completion <-__stop_machine_run
1897 bash-4043 [00] 41.267108: wait_for_common <-wait_for_completion
1898 bash-4043 [00] 41.267109: kthread_stop <-stop_machine_run
1899 bash-4043 [00] 41.267109: init_waitqueue_head <-kthread_stop
1900 bash-4043 [00] 41.267110: wake_up_process <-kthread_stop
1901 bash-4043 [00] 41.267110: try_to_wake_up <-wake_up_process
1902 bash-4043 [00] 41.267111: select_task_rq_rt <-try_to_wake_up
1905 Note, reading the trace_pipe file will block until more input is
1906 added. By changing the tracer, trace_pipe will issue an EOF. We
1907 needed to set the function tracer _before_ we "cat" the
1914 Having too much or not enough data can be troublesome in
1915 diagnosing an issue in the kernel. The file buffer_size_kb is
1916 used to modify the size of the internal trace buffers. The
1917 number listed is the number of entries that can be recorded per
1918 CPU. To know the full size, multiply the number of possible CPUS
1919 with the number of entries.
1921 # cat buffer_size_kb
1922 1408 (units kilobytes)
1924 Note, to modify this, you must have tracing completely disabled.
1925 To do that, echo "nop" into the current_tracer. If the
1926 current_tracer is not set to "nop", an EINVAL error will be
1929 # echo nop > current_tracer
1930 # echo 10000 > buffer_size_kb
1931 # cat buffer_size_kb
1932 10000 (units kilobytes)
1934 The number of pages which will be allocated is limited to a
1935 percentage of available memory. Allocating too much will produce
1938 # echo 1000000000000 > buffer_size_kb
1939 -bash: echo: write error: Cannot allocate memory
1940 # cat buffer_size_kb
1945 More details can be found in the source code, in the
1946 kernel/trace/*.c files.