Commit 0a9783b1 authored by Sasha Goldshtein's avatar Sasha Goldshtein

Added man page, reshuffled some options

parent 8058eb13
.TH gentrace 8 "2016-02-11" "USER COMMANDS"
.SH NAME
gentrace \- Trace a function and display a histogram or summary of its parameter values. Uses Linux eBPF/bcc.
.SH SYNOPSIS
.B gentrace [-h] [-p PID] [-z STRING_SIZE] [-i INTERVAL] [-c COUNT] specifier [specifier ...]
.SH DESCRIPTION
gentrace attaches to function entry and exit points, collects specified parameter
values, and stores them in a histogram or a raw counting collection that counts
the number of times a parameter value occurred. It can also filter parameter
values and instrument multiple entry points at once.
This currently only works on x86_64. Check for future versions.
.SH REQUIREMENTS
CONFIG_BPF and bcc.
.SH OPTIONS
.TP
\-h
Print usage message.
.TP
\-p PID
Trace only functions in the process PID. This filter will only apply to user-space
functions. If you only provide kernel-space probes, the filter is ignored.
.TP
\-z STRING_SIZE
When collecting string arguments (of type char*), collect up to STRING_SIZE
characters. Longer strings will be truncated.
.TP
-i INTERVAL
Print the collected data every INTERVAL seconds. The default is 1 second.
.TP
-c COUNT
Print the collected data COUNT times and then exit.
.TP
SPECIFIER
One or more probe specifications that instruct gentrace which functions to
probe, which parameters to collect, how to aggregate them, and whether to perform
any filtering. See SPECIFIER SYNTAX below.
.SH SPECIFIER SYNTAX
The general specifier syntax is as follows:
.B <raw|hist>[-ret]:[library]:function(signature)[:type:expr[:filter]]
.TP
Probe type \- "raw", "hist", "raw-ret", "hist-ret".
Indicates where to place the probe and whether the probe should collect raw
event information, or aggregate the collected values into a histogram. Raw
probes will collect the number of times every parameter value was observed,
whereas histogram probes will collect the parameter values into a histogram.
Only integral types can be used with histogram probes; there is no such limitation
for raw probes. Suffix with \-ret to indicate that the probe should be placed
at function return. This probe can only use the pseudo-variable @retval, which
is an alias for the function's return value.
.TP
Library containing the probe.
Specify the full path to the .so or executable file where the function to probe
resides. Alternatively, you can specify just the lib name: for example, "c"
refers to libc. If no library name is specified, the kernel is assumed.
.TP
The function to probe, and its signature.
The function name must match exactly for the probe to be placed. The signature,
on the other hand, is only required if you plan to collect parameter values
based on that signature. For example, if you only want to collect the first
parameter, you don't have to specify the rest of the parameters in the signature.
.TP
The type of the expression to capture.
This is the type of the keys in the histogram or raw event collection that are
collected by the probes.
.TP
The expression to capture.
These are the values that are assigned to the histogram or raw event collection.
You may use the parameters directly, or valid C expressions that involve the
parameters, such as "size % 10".
.TP
A filter applied to the captured data.
Only parameter values that pass the filter will be collected. This is any valid
C expression that refers to the parameter values, such as "fd == 1 && length > 16".
.SH EXAMPLES
.TP
Print a histogram of allocation sizes passed to kmalloc:
#
.B gentrace.py 'hist::__kmalloc(u64 size):u64:size'
.TP
Print a raw count of how many times process 1005 called malloc with an allocation size of 16 bytes:
#
.B gentrace.py -p 1005 'raw:c:malloc(size_t size):size_t:size:size==16'
.TP
Snoop on all strings returned by gets():
#
.B gentrace.py 'raw-ret:c:gets():char*:@retval'
.TP
Print raw counts of how many times writes were issued to a particular file descriptor number, in process 1005:
#
.B gentrace.py -p 1005 'raw:c:write(int fd):int:fd'
.TP
Print a histogram of error codes returned by read() in process 1005:
#
.B gentrace.py -p 1005 'hist-ret:c:read()'
.TP
Print a histogram of buffer sizes passed to write() across all processes, where the file descriptor was 1 (STDOUT):
#
.B gentrace.py 'hist:c:write(int fd, const void *buf, size_t count):size_t:count:fd==1'
.TP
Count fork() calls in libc across all processes:
#
.B gentrace.py 'raw:c:fork'
.TP
Print histograms of sleep() and nanosleep() parameter values:
#
.B gentrace.py 'hist:c:sleep(u32 seconds):u32:seconds' 'hist:c:nanosleep(struct timespec { time_t tv_sec; long tv_nsec; } *req):long:req->tv_nsec'
.TP
Spy on writes to STDOUT performed by process 2780, up to a string size of 120 characters:
#
.B gentrace.py -p 2780 -z 120 'raw:c:write(int fd, char* buf, size_t len):char*:buf:fd==1'
.SH SOURCE
This is from bcc.
.IP
https://github.com/iovisor/bcc
.PP
Also look in the bcc distribution for a companion _examples.txt file containing
example usage, output, and commentary for this tool.
.SH OS
Linux
.SH STABILITY
Unstable - in development.
.SH AUTHOR
Sasha Goldshtein
......@@ -3,9 +3,8 @@
# gentrace.py Trace a function and display a histogram or summary of its
# parameter values.
#
# USAGE: gentrace.py [-h] [-p PID] [-z STRING_SIZE]
# [-s SPECIFIER [SPECIFIER ...]]
# [interval] [count]
# USAGE: gentrace.py [-h] [-p PID] [-z STRING_SIZE] [-i INTERVAL]
# [-c COUNT] specifier [specifier ...]
#
# Copyright (C) 2016 Sasha Goldshtein.
......@@ -26,7 +25,6 @@ int PROBENAME(struct pt_regs *ctx SIGNATURE)
}
"""
# <raw|hist>:lib:function(signature)[:type:expr[:filter]]
def __init__(self, specifier, pid):
self.raw_spec = specifier
parts = specifier.strip().split(':')
......@@ -151,37 +149,37 @@ Where:
EXAMPLES:
gentrace.py -s "hist::__kmalloc(u64 size):u64:size"
gentrace.py "hist::__kmalloc(u64 size):u64:size"
Print a histogram of allocation sizes passed to kmalloc
gentrace.py -p 1005 -s "raw:c:malloc(size_t size):size_t:size:size==16"
gentrace.py -p 1005 "raw:c:malloc(size_t size):size_t:size:size==16"
Print a raw count of how many times process 1005 called malloc with
an allocation size of 16 bytes
gentrace.py -s "raw-ret:c:gets():char*:@retval"
gentrace.py "raw-ret:c:gets():char*:@retval"
Snoop on all strings returned by gets()
gentrace.py -p 1005 -s "raw:c:write(int fd):int:fd"
gentrace.py -p 1005 "raw:c:write(int fd):int:fd"
Print raw counts of how many times writes were issued to a particular
file descriptor number, in process 1005
gentrace.py -p 1005 -s "hist-ret:c:read()"
gentrace.py -p 1005 "hist-ret:c:read()"
Print a histogram of error codes returned by read() in process 1005
gentrace.py -s "hist:c:write(int fd, const void *buf, size_t count):size_t:count:fd==1"
gentrace.py "hist:c:write(int fd, const void *buf, size_t count):size_t:count:fd==1"
Print a histogram of buffer sizes passed to write() across all
processes, where the file descriptor was 1 (STDOUT)
gentrace.py -s "raw:c:fork"
gentrace.py "raw:c:fork"
Count fork() calls in libc across all processes
Can also use funccount.py, which is easier and more flexible
gentrace.py -s \\
gentrace.py \\
"hist:c:sleep(u32 seconds):u32:seconds" \\
"hist:c:nanosleep(struct timespec { time_t tv_sec; long tv_nsec; } *req):long:req->tv_nsec"
Print histograms of sleep() and nanosleep() parameter values
gentrace.py -p 2780 -s -z 120 "raw:c:write(int fd, char* buf, size_t len):char*:buf:fd==1"
gentrace.py -p 2780 -z 120 "raw:c:write(int fd, char* buf, size_t len):char*:buf:fd==1"
Spy on writes to STDOUT performed by process 2780, up to a string size
of 120 characters
"""
......@@ -194,16 +192,16 @@ parser.add_argument("-p", "--pid", type=int,
help="id of the process to trace (optional)")
parser.add_argument("-z", "--string-size", default=80, type=int,
help="maximum string size to read from char* arguments")
parser.add_argument("interval", nargs="?", default=1, type=int,
parser.add_argument("-i", "--interval", default=1, type=int,
help="output interval, in seconds")
parser.add_argument("count", nargs="?", type=int,
parser.add_argument("-c", "--count", type=int,
help="number of outputs")
parser.add_argument("-s", "--specifier", nargs="+", dest="specifiers",
parser.add_argument("specifier", nargs="+",
help="the probe specifiers (see examples below)")
args = parser.parse_args()
specifiers = []
for specifier in args.specifiers:
for specifier in args.specifier:
specifiers.append(Specifier(specifier, args.pid))
bpf_source = "#include <uapi/linux/ptrace.h>\n"
......
......@@ -10,7 +10,7 @@ various functions.
For example, suppose you want to find what allocation sizes are common in
your application:
# ./gentrace.py -p 2420 -s "raw:c:malloc(size_t size):size_t:size"
# ./gentrace.py -p 2420 "raw:c:malloc(size_t size):size_t:size"
[01:42:29]
raw:c:malloc(size_t size):size_t:size
COUNT EVENT
......@@ -43,7 +43,7 @@ probed and its value was 16, repeatedly.
Now, suppose you wanted a histogram of buffer sizes passed to the write()
function across the system:
# ./gentrace.py -s "hist:c:write(int fd, void *buf, size_t len):size_t:len"
# ./gentrace.py "hist:c:write(int fd, void *buf, size_t len):size_t:len"
[01:45:22]
hist:c:write(int fd, void *buf, size_t len):size_t:len
len : count distribution
......@@ -81,7 +81,7 @@ bytes, medium writes of 32-63 bytes, and larger writes of 64-127 bytes.
But these are writes across the board -- what if you wanted to focus on writes
to STDOUT?
# ./gentrace.py -s "hist:c:write(int fd, void *buf, size_t len):size_t:len:fd==1"
# ./gentrace.py "hist:c:write(int fd, void *buf, size_t len):size_t:len:fd==1"
[01:47:17]
hist:c:write(int fd, void *buf, size_t len):size_t:len:fd==1
len : count distribution
......@@ -120,7 +120,7 @@ You can also use gentrace to trace kernel functions. For example, suppose you
wanted a histogram of kernel allocation (kmalloc) sizes across the system,
printed twice with 3 second intervals:
# ./gentrace.py 3 2 -s "hist::__kmalloc(size_t size):size_t:size"
# ./gentrace.py -i 3 -c 2 "hist::__kmalloc(size_t size):size_t:size"
[01:50:00]
hist::__kmalloc(size_t size):size_t:size
size : count distribution
......@@ -143,7 +143,7 @@ hist::__kmalloc(size_t size):size_t:size
Occasionally, numeric information isn't enough and you want to capture strings.
What are the strings printed by puts() across the system?
# ./gentrace.py 10 1 -s "raw:c:puts(char *str):char*:str"
# ./gentrace.py -i 10 -c 1 "raw:c:puts(char *str):char*:str"
[01:53:54]
raw:c:puts(char *str):char*:str
COUNT EVENT
......@@ -155,7 +155,7 @@ It looks like the message "Press ENTER to start." was printed twice during the
What about reads? You could trace gets() across the system and print the
strings input by the user:
# ./gentrace.py 10 1 -s "raw-ret:c:gets():char*:@retval"
# ./gentrace.py -i 10 -c 1 "raw-ret:c:gets():char*:@retval"
[02:12:23]
raw-ret:c:gets():char*:@retval
COUNT EVENT
......@@ -165,7 +165,7 @@ raw-ret:c:gets():char*:@retval
Similarly, we could get a histogram of the error codes returned by read():
# ./gentrace.py 10 1 -s "hist-ret:c:read()"
# ./gentrace.py -i 10 -c 1 "hist-ret:c:read()"
[02:15:36]
hist-ret:c:read()
(int)ctx->ax : count distribution
......@@ -186,23 +186,23 @@ hist-ret:c:read()
USAGE message:
# ./gentrace.py -h
usage: gentrace.py [-h] [-p PID] [-z STRING_SIZE]
[-s SPECIFIERS [SPECIFIERS ...]]
[interval] [count]
usage: gentrace.py [-h] [-p PID] [-z STRING_SIZE] [-i INTERVAL] [-c COUNT]
specifier [specifier ...]
Trace a function and display a summary of its parameter values.
positional arguments:
interval output interval, in seconds
count number of outputs
specifier the probe specifiers (see examples below)
optional arguments:
-h, --help show this help message and exit
-p PID, --pid PID id of the process to trace (optional)
-z STRING_SIZE, --string-size STRING_SIZE
maximum string size to read from char* arguments
-s SPECIFIERS [SPECIFIERS ...], --specifier SPECIFIERS [SPECIFIERS ...]
the probe specifiers (see examples below)
-i INTERVAL, --interval INTERVAL
output interval, in seconds
-c COUNT, --count COUNT
number of outputs
Probe specifier syntax:
<raw|hist>[-ret]:[library]:function(signature)[:type:expr[:filter]]
......@@ -219,37 +219,37 @@ Where:
EXAMPLES:
gentrace.py -s "hist::__kmalloc(u64 size):u64:size"
gentrace.py "hist::__kmalloc(u64 size):u64:size"
Print a histogram of allocation sizes passed to kmalloc
gentrace.py -p 1005 -s "raw:c:malloc(size_t size):size_t:size:size==16"
gentrace.py -p 1005 "raw:c:malloc(size_t size):size_t:size:size==16"
Print a raw count of how many times process 1005 called malloc with
an allocation size of 16 bytes
gentrace.py -s "raw-ret:c:gets():char*:@retval"
gentrace.py "raw-ret:c:gets():char*:@retval"
Snoop on all strings returned by gets()
gentrace.py -p 1005 -s "raw:c:write(int fd):int:fd"
gentrace.py -p 1005 "raw:c:write(int fd):int:fd"
Print raw counts of how many times writes were issued to a particular
file descriptor number, in process 1005
gentrace.py -p 1005 -s "hist-ret:c:read()"
gentrace.py -p 1005 "hist-ret:c:read()"
Print a histogram of error codes returned by read() in process 1005
gentrace.py -s "hist:c:write(int fd, const void *buf, size_t count):size_t:count:fd==1"
gentrace.py "hist:c:write(int fd, const void *buf, size_t count):size_t:count:fd==1"
Print a histogram of buffer sizes passed to write() across all
processes, where the file descriptor was 1 (STDOUT)
gentrace.py -s "raw:c:fork"
gentrace.py "raw:c:fork"
Count fork() calls in libc across all processes
Can also use funccount.py, which is easier and more flexible
gentrace.py -s \
gentrace.py \
"hist:c:sleep(u32 seconds):u32:seconds" \
"hist:c:nanosleep(struct timespec { time_t tv_sec; long tv_nsec; } *req):long:req->tv_nsec"
Print histograms of sleep() and nanosleep() parameter values
gentrace.py -p 2780 -s -z 120 "raw:c:write(int fd, char* buf, size_t len):char*:buf:fd==1"
gentrace.py -p 2780 -z 120 "raw:c:write(int fd, char* buf, size_t len):char*:buf:fd==1"
Spy on writes to STDOUT performed by process 2780, up to a string size
of 120 characters
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