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uprobe.8
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.TH uprobe 8 "2014-07-20" "USER COMMANDS"
.SH NAME
uprobe \- trace a given uprobe definition. User-level dynamic tracing. Uses Linux ftrace. EXPERIMENTAL.
.SH SYNOPSIS
.B uprobe
[\-FhHsv] [\-d secs] [\-p PID] [\-L TID] {\-l target | uprobe_definition [filter]}
.SH DESCRIPTION
This will create, trace, then destroy a given uprobe definition. See
Documentation/trace/uprobetracer.txt in the Linux kernel source for the
syntax of a uprobe definition, and "uprobe -h" for examples. With this tool,
the probe alias is optional (it will default to something meaningful).
WARNING: This uses dynamic tracing of user-level functions, using some
relatively new kernel code. I have seen this cause target processes to fail,
either entering endless spin loops or crashing on illegal instructions. I
believe newer kernels (post 4.0) are relatively safer, but use caution. Test
in a lab environment, and know what you are doing, before use. Also consider
other (more developed) user-level tracers (perf_events, LTTng, etc.).
Use extreme caution with the raw address mode: eg, "p:libc:0xbf130". uprobe
does not check for instruction alignment, so tracing the wrong address (eg,
mid-way through a multi-byte instruction) will corrupt the target's memory.
Other tracers (eg, perf_events with debuginfo) check alignment.
Also beware of widespread tracing that interferes with the operation of the
system, eg, tracing libc:malloc, which by-default will trace _all_ processes.
I wrote this because I kept testing different custom uprobes at the command
line, and wanted a way to automate the steps. For generic user-level
tracing, use perf_events directly.
Since this uses ftrace, only the root user can use this tool.
.SH REQUIREMENTS
REQUIREMENTS: FTRACE and UPROBE CONFIG, which you may already have on recent
kernel versions, file(1), ldconfig(8), objdump(1), and some version of awk.
Also, currently only executes on Linux 4.0+ (see WARNING) unless -F is used.
.SH OPTIONS
.TP
\-F
Force. Trace despite kernel version warnings. Use on older kernels may expose
you to (since fixed) bugs, which can lock up or crash target processes, which
could also lock up the entire system. Test in a lab environment before use,
and consider other more developed user-level tracers (perf_events, LTTng,
etc.).
.TP
\-d seconds
Set the duration of tracing, in seconds. Trace output will be buffered and
printed at the end. This also reduces overheads by buffering in-kernel,
instead of printing events as they occur.
The ftrace buffer has a fixed size per-CPU (see
/sys/kernel/debug/tracing/buffer_size_kb). If you think events are missing,
try increasing that size.
.TP
\-h
Print usage message.
.TP
\-H
Print column headers.
.TP
\-s
Print user-level stack traces after each event. These are currently printed
in hex, and need post-processing to see user-level symbols (eg, addr2line;
I should automate that).
.TP
\-v
Show the uprobe format file only (do not trace), identifying possible variables
for use in a custom filter.
.TP
\-p PID
Only trace user-level functions when this process ID is on-CPU.
.TP
\-L TID
Only trace user-level functions when this thread ID is on-CPU.
.TP
uprobe_definition
A full uprobe definition, as documented by Documentation/trace/uprobetracer.txt
in the Linux kernel source. Note that the probe alias name is optional with
uprobe(8), and if not specified, it will default to something meaningful.
See the EXAMPLES section.
.TP
filter
An ftrace filter definition.
.SH EXAMPLES
These examples may need modification to match your target software function
names and platform's register usage. If using platform specific registers
becomes too painful in practice, consider a debuginfo-based tracer,
which can trace variables names instead (eg, perf_events).
.TP
trace readline() calls in all running "bash" executables:
#
.B uprobe p:bash:readline
.TP
trace readline() with explicit executable path:
#
.B uprobe p:/bin/bash:readline
.TP
trace the return of readline() with return value as a string:
#
.B uprobe 'r:bash:readline +0($retval):string'
.TP
trace sleep() calls in all running libc shared libraries:
#
.B uprobe p:libc:sleep
.TP
trace sleep() with register %di (x86):
#
.B uprobe 'p:libc:sleep %di'
.TP
trace this address (use caution: must be instruction aligned):
#
.B uprobe p:libc:0xbf130
.TP
trace gettimeofday() for PID 1182 only:
#
.B uprobe -p 1182 p:libc:gettimeofday
.TP
trace the return of fopen() only when it returns NULL:
#
.B uprobe 'r:libc:fopen file=$retval' 'file == 0'
.SH FIELDS
The output format depends on the kernel version, and headings can be printed
using \-H. The format is the same as the ftrace function trace format, described
in the kernel source under Documentation/trace/ftrace.txt.
Typical fields are:
.TP
TASK-PID
The process name (which could include dashes), a dash, and the process ID.
.TP
CPU#
The CPU ID, in brackets.
.TP
||||
Kernel state flags. For example, on Linux 3.16 these are for irqs-off,
need-resched, hardirq/softirq, and preempt-depth.
.TP
TIMESTAMP
Time of event, in seconds.
.TP
FUNCTION
User-level function name.
.SH OVERHEAD
This can generate a lot of trace data quickly, depending on the
frequency of the traced events. Such data will cause performance overheads.
This also works without buffering by default, printing function events
as they happen (uses trace_pipe), context switching and consuming CPU to do
so. If needed, you can try the "\-d secs" option, which buffers events
instead, reducing overhead. If you think the buffer option is losing events,
try increasing the buffer size (buffer_size_kb).
If you find a use for uprobe(8) where the overhead is prohibitive, consider
the same enabling using perf_events where overhead should be reduced.
.SH SOURCE
This is from the perf-tools collection:
.IP
https://github.com/brendangregg/perf-tools
.PP
Also look under the examples directory for a text file containing example
usage, output, and commentary for this tool.
.SH OS
Linux
.SH STABILITY
Unstable - in development.
.SH AUTHOR
Brendan Gregg
.SH SEE ALSO
kprobe(8)