DTrace scripts consist of a list of one or more probes, or instrumentation points, where each probe is associated with an action. Whenever the condition for a probe is met, the associated action is executed. For example, an action may occur when a file is opened, a process is started, or a line of code is executed. The action might be to log some information or to modify context variables. The reading and writing of context variables allows probes to share information and to cooperatively analyze the correlation of different events.
To view all probes, the administrator can execute the following command:
# dtrace -l | moreEach probe has an ID, a
PROVIDER (dtrace or fbt), a
MODULE, and a
FUNCTION NAME. Refer to dtrace(1) for
more information about this command.
The examples in this section provide an overview of how to
use two of the fully supported scripts from the
DTrace Toolkit: the
hotkernel and
procsystime scripts.
The hotkernel script is designed to
identify which function is using the most kernel time. It will
produce output similar to the following:
# cd /usr/share/dtrace/toolkit
# ./hotkernel
Sampling... Hit Ctrl-C to end.As instructed, use the Ctrl+C key combination to stop the process. Upon termination, the script will display a list of kernel functions and timing information, sorting the output in increasing order of time:
kernel`_thread_lock_flags 2 0.0%
0xc1097063 2 0.0%
kernel`sched_userret 2 0.0%
kernel`kern_select 2 0.0%
kernel`generic_copyin 3 0.0%
kernel`_mtx_assert 3 0.0%
kernel`vm_fault 3 0.0%
kernel`sopoll_generic 3 0.0%
kernel`fixup_filename 4 0.0%
kernel`_isitmyx 4 0.0%
kernel`find_instance 4 0.0%
kernel`_mtx_unlock_flags 5 0.0%
kernel`syscall 5 0.0%
kernel`DELAY 5 0.0%
0xc108a253 6 0.0%
kernel`witness_lock 7 0.0%
kernel`read_aux_data_no_wait 7 0.0%
kernel`Xint0x80_syscall 7 0.0%
kernel`witness_checkorder 7 0.0%
kernel`sse2_pagezero 8 0.0%
kernel`strncmp 9 0.0%
kernel`spinlock_exit 10 0.0%
kernel`_mtx_lock_flags 11 0.0%
kernel`witness_unlock 15 0.0%
kernel`sched_idletd 137 0.3%
0xc10981a5 42139 99.3%This script will also work with kernel modules. To use this
feature, run the script with -m:
# ./hotkernel -m
Sampling... Hit Ctrl-C to end.
^C
MODULE COUNT PCNT
0xc107882e 1 0.0%
0xc10e6aa4 1 0.0%
0xc1076983 1 0.0%
0xc109708a 1 0.0%
0xc1075a5d 1 0.0%
0xc1077325 1 0.0%
0xc108a245 1 0.0%
0xc107730d 1 0.0%
0xc1097063 2 0.0%
0xc108a253 73 0.0%
kernel 874 0.4%
0xc10981a5 213781 99.6%The procsystime script captures and
prints the system call time usage for a given process
ID (PID) or process name.
In the following example, a new instance of
/bin/csh was spawned. Then,
procsystime was executed and remained
waiting while a few commands were typed on the other incarnation
of csh. These are the results of this
test:
# ./procsystime -n csh
Tracing... Hit Ctrl-C to end...
^C
Elapsed Times for processes csh,
SYSCALL TIME (ns)
getpid 6131
sigreturn 8121
close 19127
fcntl 19959
dup 26955
setpgid 28070
stat 31899
setitimer 40938
wait4 62717
sigaction 67372
sigprocmask 119091
gettimeofday 183710
write 263242
execve 492547
ioctl 770073
vfork 3258923
sigsuspend 6985124
read 3988049784As shown, the read() system call used
the most time in nanoseconds while the
getpid() system call used the least amount
of time.
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