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ftrace: document updates

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The following updates were recommended by Elias Oltmanns and Randy Dunlap.

[ updates based on Andrew Morton's comments are still to come. ]

Signed-off-by: Steven Rostedt <srostedt@redhat.com>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
This commit is contained in:
Steven Rostedt 2008-07-14 16:41:12 -04:00 committed by Linus Torvalds
parent 17489c058e
commit a41eebab75
1 changed files with 71 additions and 63 deletions
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134
Documentation/ftrace.txt
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@ -2,8 +2,11 @@
========================
Copyright 2008 Red Hat Inc.
Author: Steven Rostedt <srostedt@redhat.com>
Author: Steven Rostedt <srostedt@redhat.com>
License: The GNU Free Documentation License, Version 1.2
Reviewers: Elias Oltmanns and Randy Dunlap
Writen for: 2.6.26-rc8 linux-2.6-tip.git tip/tracing/ftrace branch
Introduction
------------
@ -46,7 +49,7 @@ of ftrace. Here is a list of some of the key files:
that is configured.
available_tracers : This holds the different types of tracers that
has been compiled into the kernel. The tracers
have been compiled into the kernel. The tracers
listed here can be configured by echoing in their
name into current_tracer.
@ -90,11 +93,13 @@ of ftrace. Here is a list of some of the key files:
trace_entries : This sets or displays the number of trace
entries each CPU buffer can hold. The tracer buffers
are the same size for each CPU, so care must be
taken when modifying the trace_entries. The number
of actually entries will be the number given
times the number of possible CPUS. The buffers
are saved as individual pages, and the actual entries
will always be rounded up to entries per page.
taken when modifying the trace_entries. The trace
buffers are allocated in pages (blocks of memory that
the kernel uses for allocation, usually 4 KB in size).
Since each entry is smaller than a page, if the last
allocated page has room for more entries than were
requested, the rest of the page is used to allocate
entries.
This can only be updated when the current_tracer
is set to "none".
@ -114,13 +119,13 @@ of ftrace. Here is a list of some of the key files:
in performance. This also has a side effect of
enabling or disabling specific functions to be
traced. Echoing in names of functions into this
file will limit the trace to only those files.
file will limit the trace to only these functions.
set_ftrace_notrace: This has the opposite effect that
set_ftrace_filter has. Any function that is added
here will not be traced. If a function exists
in both set_ftrace_filter and set_ftrace_notrace
the function will _not_ bet traced.
in both set_ftrace_filter and set_ftrace_notrace,
the function will _not_ be traced.
available_filter_functions : When a function is encountered the first
time by the dynamic tracer, it is recorded and
@ -138,7 +143,7 @@ Here are the list of current tracers that can be configured.
ftrace - function tracer that uses mcount to trace all functions.
It is possible to filter out which functions that are
traced when dynamic ftrace is configured in.
to be traced when dynamic ftrace is configured in.
sched_switch - traces the context switches between tasks.
@ -297,13 +302,13 @@ explains which is which.
The above is mostly meaningful for kernel developers.
time: This differs from the trace output where as the trace output
contained a absolute timestamp. This timestamp is relative
to the start of the first entry in the the trace.
time: This differs from the trace file output. The trace file output
included an absolute timestamp. The timestamp used by the
latency_trace file is relative to the start of the trace.
delay: This is just to help catch your eye a bit better. And
needs to be fixed to be only relative to the same CPU.
The marks is determined by the difference between this
The marks are determined by the difference between this
current trace and the next trace.
'!' - greater than preempt_mark_thresh (default 100)
'+' - greater than 1 microsecond
@ -322,13 +327,13 @@ output. To see what is available, simply cat the file:
print-parent nosym-offset nosym-addr noverbose noraw nohex nobin \
noblock nostacktrace nosched-tree
To disable one of the options, echo in the option appended with "no".
To disable one of the options, echo in the option prepended with "no".
echo noprint-parent > /debug/tracing/iter_ctrl
To enable an option, leave off the "no".
echo sym-offest > /debug/tracing/iter_ctrl
echo sym-offset > /debug/tracing/iter_ctrl
Here are the available options:
@ -344,7 +349,7 @@ Here are the available options:
sym-offset - Display not only the function name, but also the offset
in the function. For example, instead of seeing just
"ktime_get" you will see "ktime_get+0xb/0x20"
"ktime_get", you will see "ktime_get+0xb/0x20".
sym-offset:
bash-4000 [01] 1477.606694: simple_strtoul+0x6/0xa0
@ -364,7 +369,7 @@ Here are the available options:
user applications that can translate the raw numbers better than
having it done in the kernel.
hex - similar to raw, but the numbers will be in a hexadecimal format.
hex - Similar to raw, but the numbers will be in a hexadecimal format.
bin - This will print out the formats in raw binary.
@ -381,7 +386,7 @@ sched_switch
------------
This tracer simply records schedule switches. Here's an example
on how to implement it.
of how to use it.
# echo sched_switch > /debug/tracing/current_tracer
# echo 1 > /debug/tracing/tracing_enabled
@ -470,7 +475,7 @@ interrupt from triggering or the mouse interrupt from letting the
kernel know of a new mouse event. The result is a latency with the
reaction time.
The irqsoff tracer tracks the time interrupts are disabled and when
The irqsoff tracer tracks the time interrupts are disabled to the time
they are re-enabled. When a new maximum latency is hit, it saves off
the trace so that it may be retrieved at a later time. Every time a
new maximum in reached, the old saved trace is discarded and the new
@ -519,7 +524,7 @@ The difference between the 6 and the displayed timestamp 7us is
because the clock must have incremented between the time of recording
the max latency and recording the function that had that latency.
Note the above had ftrace_enabled not set. If we set the ftrace_enabled
Note the above had ftrace_enabled not set. If we set the ftrace_enabled,
we get a much larger output:
# tracer: irqsoff
@ -570,21 +575,21 @@ vim:ft=help
Here we traced a 50 microsecond latency. But we also see all the
functions that were called during that time. Note that enabling
function tracing we endure an added overhead. This overhead may
extend the latency times. But never the less, this trace has provided
some very helpful debugging.
functions that were called during that time. Note that by enabling
function tracing, we endure an added overhead. This overhead may
extend the latency times. But nevertheless, this trace has provided
some very helpful debugging information.
preemptoff
----------
When preemption is disabled we may be able to receive interrupts but
the task can not be preempted and a higher priority task must wait
When preemption is disabled, we may be able to receive interrupts but
the task cannot be preempted and a higher priority task must wait
for preemption to be enabled again before it can preempt a lower
priority task.
The preemptoff tracer traces the places that disables preemption.
The preemptoff tracer traces the places that disable preemption.
Like the irqsoff, it records the maximum latency that preemption
was disabled. The control of preemptoff is much like the irqsoff.
@ -696,7 +701,7 @@ Notice that the __do_softirq when called doesn't have a preempt_count.
It may seem that we missed a preempt enabled. What really happened
is that the preempt count is held on the threads stack and we
switched to the softirq stack (4K stacks in effect). The code
does not copy the preempt count, but because interrupts are disabled
does not copy the preempt count, but because interrupts are disabled,
we don't need to worry about it. Having a tracer like this is good
to let people know what really happens inside the kernel.
@ -732,7 +737,7 @@ To record this time, use the preemptirqsoff tracer.
Again, using this trace is much like the irqsoff and preemptoff tracers.
# echo preemptoff > /debug/tracing/current_tracer
# echo preemptirqsoff > /debug/tracing/current_tracer
# echo 0 > /debug/tracing/tracing_max_latency
# echo 1 > /debug/tracing/tracing_enabled
# ls -ltr
@ -862,9 +867,9 @@ This is a very interesting trace. It started with the preemption of
the ls task. We see that the task had the "need_resched" bit set
with the 'N' in the trace. Interrupts are disabled in the spin_lock
and the trace started. We see that a schedule took place to run
sshd. When the interrupts were enabled we took an interrupt.
On return of the interrupt the softirq ran. We took another interrupt
while running the softirq as we see with the capital 'H'.
sshd. When the interrupts were enabled, we took an interrupt.
On return from the interrupt handler, the softirq ran. We took another
interrupt while running the softirq as we see with the capital 'H'.
wakeup
@ -876,9 +881,9 @@ time it executes. This is also known as "schedule latency".
I stress the point that this is about RT tasks. It is also important
to know the scheduling latency of non-RT tasks, but the average
schedule latency is better for non-RT tasks. Tools like
LatencyTop is more appropriate for such measurements.
LatencyTop are more appropriate for such measurements.
Real-Time environments is interested in the worst case latency.
Real-Time environments are interested in the worst case latency.
That is the longest latency it takes for something to happen, and
not the average. We can have a very fast scheduler that may only
have a large latency once in a while, but that would not work well
@ -889,8 +894,8 @@ tasks that are unpredictable will overwrite the worst case latency
of RT tasks.
Since this tracer only deals with RT tasks, we will run this slightly
different than we did with the previous tracers. Instead of performing
an 'ls' we will run 'sleep 1' under 'chrt' which changes the
differently than we did with the previous tracers. Instead of performing
an 'ls', we will run 'sleep 1' under 'chrt' which changes the
priority of the task.
# echo wakeup > /debug/tracing/current_tracer
@ -924,9 +929,9 @@ wakeup latency trace v1.1.5 on 2.6.26-rc8
vim:ft=help
Running this on an idle system we see that it only took 4 microseconds
Running this on an idle system, we see that it only took 4 microseconds
to perform the task switch. Note, since the trace marker in the
schedule is before the actual "switch" we stop the tracing when
schedule is before the actual "switch", we stop the tracing when
the recorded task is about to schedule in. This may change if
we add a new marker at the end of the scheduler.
@ -992,12 +997,15 @@ ksoftirq-7 1d..4 50us : schedule (__cond_resched)
The interrupt went off while running ksoftirqd. This task runs at
SCHED_OTHER. Why didn't we see the 'N' set early? This may be
a harmless bug with x86_32 and 4K stacks. The need_reched() function
that tests if we need to reschedule looks on the actual stack.
Where as the setting of the NEED_RESCHED bit happens on the
task's stack. But because we are in a hard interrupt, the test
is with the interrupts stack which has that to be false. We don't
see the 'N' until we switch back to the task's stack.
a harmless bug with x86_32 and 4K stacks. On x86_32 with 4K stacks
configured, the interrupt and softirq runs with their own stack.
Some information is held on the top of the task's stack (need_resched
and preempt_count are both stored there). The setting of the NEED_RESCHED
bit is done directly to the task's stack, but the reading of the
NEED_RESCHED is done by looking at the current stack, which in this case
is the stack for the hard interrupt. This hides the fact that NEED_RESCHED
has been set. We don't see the 'N' until we switch back to the task's
assigned stack.
ftrace
------
@ -1067,10 +1075,10 @@ this works is the mcount function call (placed at the start of
every kernel function, produced by the -pg switch in gcc), starts
of pointing to a simple return.
When dynamic ftrace is initialized, it calls kstop_machine to make it
act like a uniprocessor so that it can freely modify code without
worrying about other processors executing that same code. At
initialization, the mcount calls are change to call a "record_ip"
When dynamic ftrace is initialized, it calls kstop_machine to make
the machine act like a uniprocessor so that it can freely modify code
without worrying about other processors executing that same code. At
initialization, the mcount calls are changed to call a "record_ip"
function. After this, the first time a kernel function is called,
it has the calling address saved in a hash table.
@ -1085,8 +1093,8 @@ traced, is that we can now selectively choose which functions we
want to trace and which ones we want the mcount calls to remain as
nops.
Two files that contain to the enabling and disabling of recorded
functions are:
Two files are used, one for enabling and one for disabling the tracing
of recorded functions. They are:
set_ftrace_filter
@ -1094,7 +1102,7 @@ and
set_ftrace_notrace
A list of available functions that you can add to this files is listed
A list of available functions that you can add to these files is listed
in:
available_filter_functions
@ -1133,9 +1141,9 @@ sys_nanosleep
Perhaps this isn't enough. The filters also allow simple wild cards.
Only the following is currently available
Only the following are currently available
<match>* - will match functions that begins with <match>
<match>* - will match functions that begin with <match>
*<match> - will match functions that end with <match>
*<match>* - will match functions that have <match> in it
@ -1187,7 +1195,7 @@ This is because the '>' and '>>' act just like they do in bash.
To rewrite the filters, use '>'
To append to the filters, use '>>'
To clear out a filter so that all functions will be recorded again.
To clear out a filter so that all functions will be recorded again:
# echo > /debug/tracing/set_ftrace_filter
# cat /debug/tracing/set_ftrace_filter
@ -1246,8 +1254,8 @@ ftraced
As mentioned above, when dynamic ftrace is configured in, a kernel
thread wakes up once a second and checks to see if there are mcount
calls that need to be converted into nops. If there is not, then
it simply goes back to sleep. But if there is, it will call
calls that need to be converted into nops. If there are not any, then
it simply goes back to sleep. But if there are some, it will call
kstop_machine to convert the calls to nops.
There may be a case that you do not want this added latency.
@ -1262,8 +1270,8 @@ mcount calls to nops. Remember that there's a large overhead
to calling mcount. Without this kernel thread, that overhead will
exist.
Any write to the ftraced_enabled file will cause the kstop_machine
to run if there are recorded calls to mcount. This means that a
If there are recorded calls to mcount, any write to the ftraced_enabled
file will cause the kstop_machine to run. This means that a
user can manually perform the updates when they want to by simply
echoing a '0' into the ftraced_enabled file.
@ -1315,7 +1323,7 @@ trace entries
Having too much or not enough data can be troublesome in diagnosing
some issue in the kernel. The file trace_entries is used to modify
the size of the internal trace buffers. The numbers listed
the size of the internal trace buffers. The number listed
is the number of entries that can be recorded per CPU. To know
the full size, multiply the number of possible CPUS with the
number of entries.
@ -1323,7 +1331,7 @@ number of entries.
# cat /debug/tracing/trace_entries
65620
Note, to modify this you must have tracing fulling disabled. To do that,
Note, to modify this, you must have tracing completely disabled. To do that,
echo "none" into the current_tracer.
# echo none > /debug/tracing/current_tracer
@ -1344,7 +1352,7 @@ it will add them.
This shows us that 85 entries can fit on a single page.
The number of pages that will be allocated is a percentage of available
memory. Allocating too much will produces an error.
memory. Allocating too much will produce an error.
# echo 1000000000000 > /debug/tracing/trace_entries
-bash: echo: write error: Cannot allocate memory