Provided by: uftrace_0.9.3-1ubuntu1_amd64 
NAME
uftrace-record - Run a command and record its trace data
SYNOPSIS
uftrace record [options] COMMAND [command-options]
DESCRIPTION
This command runs COMMAND and gathers function trace data from it, and saves it into files
under the uftrace data directory - without displaying anything.
This data can then be inspected later on, using uftrace replay or uftrace report.
RECORD OPTIONS
-A SPEC, --argument=SPEC
Record function arguments. This option can be used more than once. Implies
--srcline. See ARGUMENTS.
-R SPEC, --retval=SPEC
Record function return values. This option can be used more than once. Implies
--srcline. See ARGUMENTS.
-P FUNC, --patch=FUNC
Patch FUNC dynamically. This option can be used more than once. See DYNAMIC
TRACING.
-Z SIZE, --size-filter=SIZE
Patch functions bigger than SIZE bytes dynamically. See DYNAMIC TRACING.
-E EVENT, --event=EVENT
Enable event tracing. The event should be available on the system.
-S SCRIPT_PATH, --script=SCRIPT_PATH
Run a given script to do additional work at the entry and exit of function during
target program execution. The type of script is detected by the postfix such as
`.py' for python. See SCRIPT EXECUTION.
-W, --watch=POINT
Add watch point to display POINT if the value is changed. See WATCH POINT.
-a, --auto-args
Automatically record arguments and return values of known functions. These are
usually functions in standard (C language or system) libraries but if debug info is
available it includes functions in the user program. Implies --srcline.
-l, --nest-libcall
Trace function calls between libraries. By default, uftrace only record library
call from the main executable. Implies --force.
-k, --kernel
Trace kernel functions as well as user functions. Only kernel entry/exit functions
will be traced by default. Use the --kernel-depth option to override this.
-K DEPTH, --kernel-depth=DEPTH
Set kernel max function depth separately. Implies --kernel.
-H HOST, --host=HOST
Send trace data to given host via the network, not writing to files. The uftrace
recv command should be run on the destination host to receive the data.
--port=PORT
When sending data to the network (with -H), use the given port instead of the
default (8090).
--signal=TRG
Set trigger on selected signals rather than functions. But there are restrictions
so only a few of trigger actions are support for signals. The available actions
are: trace_on, trace_off, finish. This option can be used more than once. See
TRIGGERS.
--nop Do not record any functions. This is a no-op and only meaningful for performance
comparisons.
--force
Allow running uftrace even if some problems occur. When uftrace record finds no
mcount symbol (which is generated by compiler) in the executable, it quits with an
error message since uftrace can not trace the program. However, it is possible
that the user is only interested in functions within a dynamically-linked library,
in which case this option can be used to cause uftrace to run the program
regardless. Also, the -A/--argument and -R/--retval options work only for binaries
built with -pg, so uftrace will normally exit when it tries to run binaries built
without that option. This option ignores the warning and goes on tracing without
the argument and/or return value.
--time Print running time of children in time(1)-style.
COMMON OPTIONS
-F FUNC, --filter=FUNC
Set filter to trace selected functions only. This option can be used more than
once. See FILTERS.
-N FUNC, --notrace=FUNC
Set filter not to trace selected functions (or the functions called underneath
them). This option can be used more than once. See FILTERS.
-C FUNC, --caller-filter=FUNC
Set filter to trace callers of selected functions only. This option can be used
more than once. See FILTERS.
-T TRG, --trigger=TRG
Set trigger on selected functions. This option can be used more than once. See
TRIGGERS.
-D DEPTH, --depth=DEPTH
Set global trace limit in nesting level. See FILTERS.
-t TIME, --time-filter=TIME
Do not show functions which run under the time threshold. If some functions
explicitly have the `trace' trigger applied, those are always traced regardless of
execution time. See FILTERS.
--no-libcall
Do not record library function invocations. Library calls are normally traced by
hooking the dynamic linker’s resolve function in the PLT. One can disable it with
this option.
--no-event
Disable event recording which is used by default. Note that explicit event tracing
by --event option is not affected by this.
--match=TYPE
Use pattern match using TYPE. Possible types are regex and glob. Default is
regex.
--disable
Start uftrace with tracing disabled. This is only meaningful when used with a
trace_on trigger.
RECORD CONFIG OPTIONS
-L PATH, --library-path=PATH
Load necessary internal libraries from this path. This is mostly for testing
purposes.
-b SIZE, --buffer=SIZE
Size of internal buffer in which trace data will be saved. Default size is 128k.
--kernel-buffer=SIZE
Set kernel tracing buffer size. The default value (in the kernel) is 1408k.
--no-pltbind
Do not bind dynamic symbol address. This option uses the LD_BIND_NOT environment
variable to trace library function calls which might be missing due to concurrent
(first) accesses. It is not meaningful to use this option with the --no-libcall
option.
--max-stack=DEPTH
Set the max function stack depth for tracing. Default is 1024.
--num-thread=NUM
Use NUM threads to record trace data. Default is 1/4 of online CPUs (but when full
kernel tracing is enabled, it will use the full number of CPUs).
--libmcount-single
Use single thread version of libmcount for faster recording. This is ignored if
the target program links with the pthread library.
--rt-prio=PRIO
Boost priority of recording threads to real-time (FIFO) with priority of PRIO.
This is particularly useful for high-volume data such as full kernel tracing.
--keep-pid
Retain same pid for traced program. For some daemon processes, it is important to
have same pid when forked. Running under uftrace normally changes pid as it calls
fork() again internally.
--no-randomize-addr
Disable ASLR (Address Space Layout Randomization). It makes the target process fix
its address space layout.
--srcline
Enable recording source line in the debug info.
FILTERS
The uftrace tool supports filtering out uninteresting functions. Filtering is highly
recommended since it helps users focus on the interesting functions and reduces the data
size. When uftrace is called it receives two types of function filter; an opt-in filter
with -F/--filter and an opt-out filter with -N/--notrace. These filters can be applied
either at record time or replay time.
The first one is an opt-in filter. By default, it doesn’t trace anything. But when one
of the specified functions is executed, tracing is started. When the function returns,
tracing is stopped again.
For example, consider a simple program which calls a(), b() and c() in turn.
$ cat abc.c
void c(void) {
/* do nothing */
}
void b(void) {
c();
}
void a(void) {
b();
}
int main(void) {
a();
return 0;
}
$ gcc -pg -o abc abc.c
Normally uftrace will trace all the functions from main() to c().
$ uftrace record ./abc
$ uftrace replay
# DURATION TID FUNCTION
138.494 us [ 1234] | __cxa_atexit();
[ 1234] | main() {
[ 1234] | a() {
[ 1234] | b() {
3.880 us [ 1234] | c();
5.475 us [ 1234] | } /* b */
6.448 us [ 1234] | } /* a */
8.631 us [ 1234] | } /* main */
But when the -F b filter option is used, it will not trace main() or a() but only b() and
c().
$ uftrace record -F b ./abc
$ uftrace replay
# DURATION TID FUNCTION
[ 1234] | b() {
3.880 us [ 1234] | c();
5.475 us [ 1234] | } /* b */
The second type of filter is opt-out. By default, everything is traced, but when one of
the specified functions is executed, tracing stops. When the excluded function returns,
tracing is started again.
In the above example, you can omit the function b() and all calls it makes with the -N
option.
$ uftrace record -N b ./abc
$ uftrace replay
# DURATION TID FUNCTION
138.494 us [ 1234] | __cxa_atexit();
[ 1234] | main() {
6.448 us [ 1234] | a();
8.631 us [ 1234] | } /* main */
If users only care about specific functions and want to know how they are called, one can
use the caller filter. It makes the function as leaf and records the parent functions to
the function.
$ uftrace record -C b ./abc
$ uftrace replay
# DURATION TID FUNCTION
[ 1234] | main() {
[ 1234] | a() {
5.475 us [ 1234] | b();
6.448 us [ 1234] | } /* a */
8.631 us [ 1234] | } /* main */
In the above example, functions not in the calling path were not shown. Also the function
`c' - which is a child of the function `b' - is also hidden.
In addition, you can limit the nesting level of functions with the -D option.
$ uftrace record -D 3 ./abc
$ uftrace replay
# DURATION TID FUNCTION
138.494 us [ 1234] | __cxa_atexit();
[ 1234] | main() {
[ 1234] | a() {
5.475 us [ 1234] | b();
6.448 us [ 1234] | } /* a */
8.631 us [ 1234] | } /* main */
In the above example, uftrace only records functions up to a depth of 3, so leaf function
c() was omitted. Note that the -D option works with -F.
Sometimes it’s useful to see long-running functions only. This is good because there are
usually many tiny functions that are not interesting. The -t/--time-filter option
implements the time-based filter that only records functions which run longer than the
given threshold. In the above example, the user might want to see functions running more
than 5 micro-seconds like below:
$ uftrace record -t 5us ./abc
$ uftrace replay
# DURATION TID FUNCTION
138.494 us [ 1234] | __cxa_atexit();
[ 1234] | main() {
[ 1234] | a() {
5.475 us [ 1234] | b();
6.448 us [ 1234] | } /* a */
8.631 us [ 1234] | } /* main */
The -t/--time-filter option works for user-level functions only. It does not work for
recording kernel functions, but they can be hidden in replay, report, dump and graph
commands with -t/--time-filter option.
You can also set triggers on filtered functions. See TRIGGERS section below for details.
When kernel function tracing is enabled, you can also set the filters on kernel functions
by marking the symbol with the @kernel modifier. The following example will show all user
functions and the (kernel) page fault handler.
$ sudo uftrace -k -F '.*page_fault@kernel' ./abc
# DURATION TID FUNCTION
[14721] | main() {
7.713 us [14721] | __do_page_fault();
6.600 us [14721] | __do_page_fault();
6.544 us [14721] | __do_page_fault();
[14721] | a() {
[14721] | b() {
[14721] | c() {
0.860 us [14721] | getpid();
2.346 us [14721] | } /* c */
2.956 us [14721] | } /* b */
3.340 us [14721] | } /* a */
79.086 us [14721] | } /* main */
TRIGGERS
The uftrace tool supports triggering actions on selected function calls (with or without
filters) and/or signals. Currently supported triggers are listed below. The BNF for
trigger specification is as follows:
<trigger> := <symbol> "@" <actions>
<actions> := <action> | <action> "," <actions>
<action> := "depth="<num> | "trace" | "trace_on" | "trace_off" |
"time="<time_spec> | "read="<read_spec> | "finish" |
"filter" | "notrace" | "recover"
<time_spec> := <num> [ <time_unit> ]
<time_unit> := "ns" | "nsec" | "us" | "usec" | "ms" | "msec" | "s" | "sec" | "m" | "min"
<read_spec> := "proc/statm" | "page-fault" | "pmu-cycle" | "pmu-cache" | "pmu-branch"
The depth trigger is to change filter depth during execution of the function. It can be
used to apply different filter depths for different functions.
The following example shows how triggers work. The global filter maximum depth is 5, but
when function b() is called, it is changed to 1, so functions below b() will not shown.
$ uftrace record -D 5 -T 'b@depth=1' ./abc
$ uftrace replay
# DURATION TID FUNCTION
138.494 us [ 1234] | __cxa_atexit();
[ 1234] | main() {
[ 1234] | a() {
5.475 us [ 1234] | b();
6.448 us [ 1234] | } /* a */
8.631 us [ 1234] | } /* main */
The backtrace trigger is only meaningful in the replay command.
The trace_on and trace_off actions (the _ can be omitted as traceon and traceoff) control
whether uftrace records the specified functions or not.
The `recover' trigger is for some corner cases in which the process accesses the callstack
directly. For now it’s not necessary to call it as uftrace does the job automatically.
The `time' trigger is to change time filter setting during execution of the function. It
can be used to apply different time filter for different functions.
The read trigger is to read some information at runtime. The result will be recorded as
(builtin) events at the beginning and the end of a given function. As of now, following
events are supported:
• “proc/statm”: process memory stat from /proc filesystem
• “page-fault”: number of page faults using getrusage(2)
• “pmu-cycle”: cpu cycles and instructions using Linux perf-event syscall
• “pmu-cache”: (cpu) cache-references and misses using Linux perf-event syscall
• “pmu-branch”: branch instructions and misses using Linux perf-event syscall
The results are printed as events (comments) like below.
$ uftrace record -T a@read=proc/statm ./abc
$ uftrace replay
# DURATION TID FUNCTION
[ 1234] | main() {
[ 1234] | a() {
[ 1234] | /* read:proc/statm (size=6808KB, rss=776KB, shared=712KB) */
[ 1234] | b() {
[ 1234] | c() {
1.448 us [ 1234] | getpid();
10.270 us [ 1234] | } /* c */
11.250 us [ 1234] | } /* b */
[ 1234] | /* diff:proc/statm (size=+4KB, rss=+0KB, shared=+0KB) */
18.380 us [ 1234] | } /* a */
19.537 us [ 1234] | } /* main */
The `finish' trigger is to end recording. The process still can run and this can be
useful to trace unterminated processes like daemon.
The `filter' and `notrace' triggers have same effect as -F/--filter and -N/--notrace
options respectively.
Triggers only work for user-level functions for now.
The trigger can be used for signals as well. This is done by signal trigger with --signal
option. The syntax is similar to function trigger but only “trace_on”, “trace_off” and
“finish” trigger actions are supported.
$ uftrace record --signal 'SIGUSR1@finish' ./some-daemon
ARGUMENTS
The uftrace tool supports recording function arguments and/or return values using the
-A/--argument and -R/--retval options respectively. The syntax is very similar to that of
triggers:
<argument> := <symbol> [ "@" <specs> ]
<specs> := <spec> | <spec> "," <spec>
<spec> := ( <int_spec> | <float_spec> | <ret_spec> )
<int_spec> := "arg" N [ "/" <format> [ <size> ] ] [ "%" ( <reg> | <stack> ) ]
<float_spec> := "fparg" N [ "/" ( <size> | "80" ) ] [ "%" ( <reg> | <stack> ) ]
<ret_spec> := "retval" [ "/" <format> [ <size> ] ]
<format> := "d" | "i" | "u" | "x" | "s" | "c" | "f" | "S" | "p"
<size> := "8" | "16" | "32" | "64"
<reg> := <arch-specific register name> # "rdi", "xmm0", "r0", ...
<stack> := "stack" [ "+" ] <offset>
The -A/--argument option takes a symbol name pattern and its optional specs. The spec is
started by argN where N is an index of the arguments. The index starts from 1 and
corresponds to the argument passing order of the calling convention on the system. Note
that the indexes of arguments are separately counted for integer (or pointer) and
floating-point type, and they can interfere depending on the calling convention. The argN
is for integer arguments and fpargN is for floating-point arguments.
Users can optionally specify a format and size for the arguments and/or return values.
The “d” format or without format field, uftrace treats them as `long int' type for
integers and `double' for floating-point numbers. The “i” format makes it signed integer
type and “u” format is for unsigned type. Both are printed as decimal while “x” format
makes it printed as hexadecimal. The “s” format is for null-terminated string type and
“c” format is for character type. The “f” format is for floating-point type and is
meaningful only for return value (generally). Note that fpargN doesn’t take the format
field since it’s always floating-point. The “S” format is for std::string, but it only
supports libstdc++ library as of yet. Finally, the “p” format is for function pointer.
Once the target address is recorded, it will be displayed as function name.
Please beware when using string type arguments since it can crash the program if the
(pointer) value is invalid. Actually uftrace tries to keep track of valid ranges of
process address space but it might miss some corner cases.
It is also possible to specify a certain register name or stack offset for arguments (but
not for return value). The following register names can be used for argument:
• x86: rdi, rsi, rdx, rcx, r8, r9 (for integer), xmm[0-7] (for floating-point)
• arm: r[0-3] (for integer), s[0-15] or d[0-7] (for floating-point)
Examples are below:
$ uftrace record -A main@arg1/x -R main@retval/i32 ./abc
$ uftrace replay
# DURATION TID FUNCTION
138.494 us [ 1234] | __cxa_atexit();
[ 1234] | main(0x1) {
[ 1234] | a() {
[ 1234] | b() {
3.880 us [ 1234] | c();
5.475 us [ 1234] | } /* b */
6.448 us [ 1234] | } /* a */
8.631 us [ 1234] | } = 0; /* main */
$ uftrace record -A puts@arg1/s -R puts@retval ./hello
Hello world
$ uftrace replay
# DURATION TID FUNCTION
1.457 us [21534] | __monstartup();
0.997 us [21534] | __cxa_atexit();
[21534] | main() {
7.226 us [21534] | puts("Hello world") = 12;
8.708 us [21534] | } /* main */
Note that these arguments and return value are recorded only if the executable was built
with the -pg option. Executables built with -finstrument-functions will ignore it except
for library calls. Recording of arguments and return values only works with user-level
functions for now.
If the target program is built with debug info like DWARF, uftrace can identify number of
arguments and their types automatically (when built with libdw). Also arguments and
return value of some well-known library functions are provided even if the debug info is
not available. In these cases user don’t need to specify spec of the arguments and return
value manually - just a function name (or pattern) is enough. In fact, manual argspec
will suppress the automatic argspec.
For example, the above example can be written like below:
$ uftrace record -A . -R main ./hello
Hello world
$ uftrace replay -F main
# DURATION TID FUNCTION
[ 18948] | main(1, 0x7ffeeb7590b8) {
7.183 us [ 18948] | puts("Hello world");
9.832 us [ 18948] | } = 0; /* main */
Note that argument pattern (“.”) matches to any character so it recorded all (supported)
functions. It shows two arguments for “main” and a single string argument for “puts”. If
you simply want to see all arguments and return values of every functions (if supported),
use -a/--auto-args option.
DYNAMIC TRACING
The uftrace tool supports dynamic function tracing which can be enabled at runtime
(load-time, to be precise) on x86_64. Before recording functions, normally you need to
build the target program with -pg (or -finstrument-functions), then it has some
performance impact because all functions call mcount().
With dynamic tracing, you can trace specific functions only given by the -P/--patch
option. With capstone disassembly engine you even don’t need to (re)compile the target
with the option above. Now uftrace can analyze the instructions and (if possible) it can
copy them to a different place and rewrite it to call mcount() function) so that it can be
traced by uftrace. After that the control is passed to the copied instructions and then
returned back to the remaining instructions.
If the capstone is not available, you need to add some more compiler (gcc) options when
building the target program. The gcc 5.1 or more recent versions provide -mfentry and
-mnop-mcount options which add instrumentation code (i.e. calling mcount() function) at
the very beginning of a function and convert the instruction to a NOP. Then it has almost
zero performance overhead when running in a normal condition. The uftrace can selectively
convert it back to call mcount() using -P option.
The following example shows an error message when normally running uftrace. Because the
binary doesn’t call any instrumentation code (i.e. `mcount').
$ gcc -o abc tests/s-abc.c
$ uftrace abc
uftrace: /home/namhyung/project/uftrace/cmd-record.c:1305:check_binary
ERROR: Can't find 'mcount' symbol in the 'abc'.
It seems not to be compiled with -pg or -finstrument-functions flag
which generates traceable code. Please check your binary file.
But when the -P a patch option is used, and then only it can dynamically trace a().
$ uftrace record --no-libcall -P a abc
$ uftrace replay
# DURATION TID FUNCTION
0.923 us [19379] | a();
In addition, you can enable all functions using `.' (for glob, ’*’) that matches to any
character in a regex pattern with P option.
$ uftrace record --no-libcall -P . abc
$ uftrace replay
# DURATION TID FUNCTION
[19387] | main() {
[19387] | a() {
[19387] | b() {
0.940 us [19387] | c();
2.030 us [19387] | } /* b */
2.451 us [19387] | } /* a */
3.289 us [19387] | } /* main */
Clang/LLVM 4.0 provides a dynamic instrumentation technique called X-ray
(http://llvm.org/docs/XRay.html). It’s similar to a combination of gcc -mfentry
-mnop-mcount and -finstrument-functions. The uftrace also supports dynamic tracing on the
executables built with the X-ray.
For example, you can build the target program by clang with the below option and equally
use -P option for dynamic tracing like below:
$ clang -fxray-instrument -fxray-instruction-threshold=1 -o abc-xray tests/s-abc.c
$ uftrace record -P main abc-xray
$ uftrace replay
# DURATION TID FUNCTION
[11093] | main() {
1.659 us [11093] | getpid();
5.963 us [11093] | } /* main */
$ uftrace record -P . abc-xray
$ uftrace replay
# DURATION TID FUNCTION
[11098] | main() {
[11098] | a() {
[11098] | b() {
[11098] | c() {
0.753 us [11098] | getpid();
1.430 us [11098] | } /* c */
1.915 us [11098] | } /* b */
2.405 us [11098] | } /* a */
3.005 us [11098] | } /* main */
SCRIPT EXECUTION
The uftrace tool supports script execution for each function entry and exit. The
supported script is only Python 2.7 as of now.
The user can write four functions. `uftrace_entry' and `uftrace_exit' are executed
whenever each function is executed at the entry and exit. However `uftrace_begin' and
`uftrace_end' are only executed once when the target program begins and ends.
$ cat scripts/simple.py
def uftrace_begin(ctx):
print("program begins...")
def uftrace_entry(ctx):
func = ctx["name"]
print("entry : " + func + "()")
def uftrace_exit(ctx):
func = ctx["name"]
print("exit : " + func + "()")
def uftrace_end():
print("program is finished")
The above script can be executed in record time as follows:
$ uftrace record -S scripts/simple.py -F main tests/t-abc
program begins...
entry : main()
entry : a()
entry : b()
entry : c()
entry : getpid()
exit : getpid()
exit : c()
exit : b()
exit : a()
exit : main()
program is finished
The `ctx' variable is a dictionary type that contains the below information.
/* context information passed to uftrace_entry(ctx) and uftrace_exit(ctx) */
script_context = {
int tid;
int depth;
long timestamp;
long duration; # exit only
long address;
string name;
list args; # entry only (if available)
value retval; # exit only (if available)
};
/* context information passed to uftrace_begin(ctx) */
script_context = {
bool record; # True if it runs at record time, otherwise False
string version; # uftrace version info
list cmds; # execution commands
};
Each field in `script_context' can be read inside the script. Please see
uftrace-script(1) for details about scripting.
WATCH POINT
The uftrace watch point is to display certain value only if it’s changed. It’s
conceptually same as debugger’s but only works at function entry and exit so it might miss
some updates.
As of now, following watch points are supported:
• “cpu” : cpu number current task is running on
Like read triggers, the result is displayed as event (comment):
$ uftrace -W cpu tests/t-abc
# DURATION TID FUNCTION
[ 19060] | main() {
[ 19060] | /* watch:cpu (cpu=8) */
[ 19060] | a() {
[ 19060] | b() {
[ 19060] | c() {
2.365 us [ 19060] | getpid();
8.002 us [ 19060] | } /* c */
8.690 us [ 19060] | } /* b */
9.350 us [ 19060] | } /* a */
12.479 us [ 19060] | } /* main */
SEE ALSO
uftrace(1), uftrace-replay(1), uftrace-report(1), uftrace-recv(1), uftrace-graph(1),
uftrace-script(1), uftrace-tui(1)
AUTHORS
Namhyung Kim <namhyung@gmail.com>.