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VOOZH | about |
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VOOZH | about |
Brendan's site:
Start HereThe following are open source tools and examples that use DTrace, an implementation of dynamic tracing that is available in different OSes (Solaris, Mac OS X, FreeBSD, ...). DTrace helps troubleshoot problems on servers by providing new detailed views of application and system internals, to a level that was previously difficult or impossible to access. It provides a language to write DTrace scripts that is similar to C and awk and is event based. For a longer summary, see the wikipedia DTrace entry.
This website contains many of my first DTrace scripts, written during 2004-5 on pre-release Solaris 10. These were developed into a collection called the DTraceToolkit, which contains newer versions of the scripts found here. My most recent collection was published in the DTrace book (Prentice Hall, 2011) pictured on the right, which contains many new scripts. Those new scripts can be found on the www.dtracebook.com website.
On this page: Linux, Guide, DTraceToolkit, DTrace One-Liners, Scripts, Examples, DTraceTazTool, DExplorer, Links.
DTrace is available for Mac OS X, FreeBSD, and the Solaris family of operating systems: Solaris 10, Oracle Solaris 11, SmartOS, OmniOS, and anything else based on the illumos kernel.
Many of the DTrace scripts on this page were originally written for Solaris 10. Some will work on other operating systems with out changes, some will require minor tweaks to get running.
As of Linux 4.9, the Linux kernel finally has similar raw capabilities as DTrace. This is the culmination of many tracing projects and technologies that were merged in the Linux kernel over the years, including: profiling and PMC events (perf_events), kernel static tracing (tracepoints), kernel dynamic tracing (kprobes), and user dynamic tracing (uprobes). The prior Linux tracers were ftrace and perf_events. The new Linux tracer, which builds upon all of these, is enhanced BPF with multiple front-ends available: in particular, bcc and bpftrace. See my posts about it: DTrace for Linux 2016 (eBPF) and DTrace for Linux 2018 (bpftrace). I also have a page on Linux eBPF Tracing.
If you want a DTraceToolkit-like experience (canned tools), check out bcc. If you want a DTrace-like experience (D programming), check out bpftrace. I've published tools for both.
For Linux tracing prior to eBPF, I wrote a collection of ftrace and perf_events tools, similar to the DTraceToolkit, that run on older Linux kernels: perf-tools, which I also talked about at LISA, Linux Performance Analysis: New Tools and Old Secrets.
What about the add ons, like SystemTap, ktap, etc? Now that eBPF has been included in 4.9, all add ons should be looking at using eBPF for back end capabilities. That started in 2017 and will continue in 2019, as 4.9 kernels are rolled out and there's more demand for eBPF tools. To see some older material on these add on tracers, I did have a ktap page, and gave a talk in 2014, From DTrace To Linux. As for DTrace itself, there are two projects to port it to Linux: the dtrace4linux project, and, a different port for Oracle Linux. These ports do not appear to have momentum, whereas bcc/eBPF does.
How does one get started with DTrace? You can use DTrace by just running scripts, or, you can write them yourself.
Not everyone has the time to sit down and write a DTrace script from scratch, or the time to learn how. Not to worry, there are many scripts online to download and use. You can:
Some people will write their own customised DTrace scripts to troubleshoot faults or solve performance issues.
To get started writing your own scripts:
Note: Many of the DTrace scripts on this site have been wrapped in the Bourne shell or Perl to provide command line options, allowing tools to be created for system administrators that are intuitive and easy to learn, by following the existing conventions and style of other Unix tools.
See the DTraceToolkit website (and please update links to point to it).
These are handy one liners to use at the command line. dtrace_oneliners.txt contains the full listing with examples.
dtrace -n 'proc:::exec-success { trace(curpsinfo->pr_psargs); }'
dtrace -n 'syscall::open*:entry { printf("%s %s",execname,copyinstr(arg0)); }'
dtrace -n 'syscall:::entry { @num[execname] = count(); }'
dtrace -n 'syscall:::entry { @num[probefunc] = count(); }'
dtrace -n 'syscall:::entry { @num[pid,execname] = count(); }'
dtrace -n 'sysinfo:::readch { @bytes[execname] = sum(arg0); }'
dtrace -n 'sysinfo:::writech { @bytes[execname] = sum(arg0); }'
dtrace -n 'sysinfo:::readch { @dist[execname] = quantize(arg0); }'
dtrace -n 'sysinfo:::writech { @dist[execname] = quantize(arg0); }'
dtrace -n 'io:::start { printf("%d %s %d",pid,execname,args[0]->b_bcount); }'
dtrace -n 'vminfo:::pgpgin { @pg[execname] = sum(arg0); }'
dtrace -n 'vminfo:::as_fault { @mem[execname] = sum(arg0); }'
dtrace -n 'profile-99 /pid == 189 && arg1/ { @[ustack()] = count(); }'
There are also many one-liners in the DTrace book, and as Appendix D of the Systems Performance book.
iosnoop is a program to snoop disk I/O activity. Here we can watch live what is happening on our disks, including the PID and command responsible. The output includes the block address and size of the disk operation - for the first time you can watch live what the disks are up to.
# iosnoop UID PID D BLOCK SIZE COMM PATHNAME 100 15795 R 3808 8192 tar /usr/bin/eject 100 15795 R 35904 6144 tar /usr/bin/eject 100 15795 R 39828 6144 tar /usr/bin/env 100 15795 R 3872 8192 tar /usr/bin/expr 100 15795 R 21120 7168 tar /usr/bin/expr 100 15795 R 43680 6144 tar /usr/bin/false 100 15795 R 44176 6144 tar /usr/bin/fdetach 100 15795 R 3920 8192 tar /usr/bin/fdformat 100 15795 R 3936 8192 tar /usr/bin/fdformat 100 15795 R 4080 8192 tar /usr/bin/fdformat 100 15795 R 9680 3072 tar /usr/bin/fdformat [...]
The following illustrates disk activity caused by familiar Unix commands. iosnoop was executed on a Solaris 10 x86 server and the data was plotted - disk head location (red) and transfer size (blue). Click for larger versions:
Here a tar command was executed (tar cvf /dev/null /var) to archive a directory, while iosnoop captured the first 2 seconds of disk activity. Some scattered activity is observed while tar is reading through directories, and sequential transfers can be observed as tar encounters large files.
iotop display top disk I/O events by process. This tracks disk I/O by process, and prints a summary report that is refreshed every interval. Full example. first release. check for updates.
# iotop -C Sampling... Please wait. 2005 Jul 16 00:31:38, load: 1.03, disk_r: 5023 Kb, disk_w: 22 Kb UID PID PPID CMD DEVICE MAJ MIN D BYTES 0 27740 20320 tar cmdk0 102 16 W 23040 0 27739 20320 find cmdk0 102 0 R 668672 0 27740 20320 tar cmdk0 102 16 R 1512960 0 27740 20320 tar cmdk0 102 3 R 3108864 2005 Jul 16 00:31:43, load: 1.06, disk_r: 8234 Kb, disk_w: 0 Kb UID PID PPID CMD DEVICE MAJ MIN D BYTES 0 27739 20320 find cmdk0 102 0 R 1402880 0 27740 20320 tar cmdk0 102 3 R 7069696 [...]
execsnoop is a program to snoop process activity. As processes are executed on the server their details are printed out. Another user was logged in running a few commands which can be seen below. This is especially useful in troubleshooting short lived processes that are otherwise hard to spot. More examples.
# execsnoop UID PID PPID CMD 100 3008 2656 ls 100 3009 2656 ls -l 100 3010 2656 cat /etc/passwd 100 3011 2656 vi /etc/hosts 100 3012 2656 date 100 3013 2656 ls -l 100 3014 2656 ls 100 3015 2656 finger [...]
opensnoop is a program to snoop file opens. The filename and file handle are traced along with some process details. More examples.
# opensnoop -g UID PID PATH FD ARGS 100 3528 /var/ld/ld.config -1 cat /etc/passwd 100 3528 /usr/lib/libc.so.1 3 cat /etc/passwd 100 3528 /etc/passwd 3 cat /etc/passwd 100 3529 /var/ld/ld.config -1 cal 100 3529 /usr/lib/libc.so.1 3 cal 100 3529 /usr/share/lib/zoneinfo/Australia/NSW 3 cal 100 3530 /var/ld/ld.config -1 ls -l 100 3530 /usr/lib/libc.so.1 3 ls -l 100 3530 /var/run/name_service_door 3 ls -l 100 3530 /usr/share/lib/zoneinfo/Australia/NSW 4 ls -l 100 3531 /var/ld/ld.config -1 uname -a 100 3531 /usr/lib/libc.so.1 3 uname -a [...]
rwsnoop snoop read/write events. This is measuring reads and writes at the application level - syscalls. Full example.
# rwsnoop UID PID CMD D BYTES FILE 0 2924 sh R 128 /etc/profile 0 2924 sh R 128 /etc/profile 0 2924 sh R 128 /etc/profile 0 2924 sh R 84 /etc/profile 0 2925 quota R 757 /etc/nsswitch.conf 0 2925 quota R 0 /etc/nsswitch.conf 0 2925 quota R 668 /etc/passwd 0 2926 cat R 55 /etc/motd 0 2926 cat W 55 /devices/pseudo/pts@0:12 100 20334 sshd R 56 /devices/pseudo/clone@0:ptm 100 20334 sshd W 100 <unknown> 0 2926 cat R 0 /etc/motd 0 2927 mail R 757 /etc/nsswitch.conf 0 2927 mail R 0 /etc/nsswitch.conf 0 2927 mail R 275 /etc/group 0 2927 mail R 668 /etc/passwd 0 2924 sh R 0 /etc/profile [...]
rwtop display top read/write bytes by process. rwtop prints a summary report that is refreshed at intervals. This is measuring reads and writes at the application level - syscalls. Full example.
# rwtop 2005 Jul 24 05:00:13, load: 1.01, app_r: 38 Kb, app_w: 8 Kb UID PID PPID CMD D BYTES 0 245 1 utmpd R 4 0 20320 20347 bash R 21 100 20317 20314 sshd R 26 100 20317 20314 sshd W 68 0 2934 20320 ps W 140 0 20320 20347 bash W 216 0 7 1 svc.startd R 672 0 2935 20320 df W 1225 0 2936 20320 ls W 1466 0 2936 20320 ls R 2485 100 20334 20331 sshd R 4241 100 20334 20331 sshd W 5717 0 2934 20320 ps R 31567
tcpsnoop snoop TCP network packets by process. This analyses TCP network packets and prints the responsible PID and UID, plus standard details such as IP address and port. This captures traffic of newly created TCP connections that were established while this program was running. It can help identify which processes is causing TCP traffic. Full example. new release. check for updates.
# tcpsnoop.d UID PID LADDR LPORT DR RADDR RPORT SIZE CMD 100 20892 192.168.1.5 36398 -> 192.168.1.1 79 54 finger 100 20892 192.168.1.5 36398 -> 192.168.1.1 79 54 finger 100 20892 192.168.1.5 36398 <- 192.168.1.1 79 54 finger 0 242 192.168.1.5 23 <- 192.168.1.1 54224 54 inetd 0 242 192.168.1.5 23 -> 192.168.1.1 54224 54 inetd 0 242 192.168.1.5 23 <- 192.168.1.1 54224 54 inetd 0 242 192.168.1.5 23 <- 192.168.1.1 54224 78 inetd 0 242 192.168.1.5 23 -> 192.168.1.1 54224 54 inetd 0 20893 192.168.1.5 23 -> 192.168.1.1 54224 57 in.telnetd 0 20893 192.168.1.5 23 <- 192.168.1.1 54224 54 in.telnetd 0 20893 192.168.1.5 23 -> 192.168.1.1 54224 78 in.telnetd 0 20893 192.168.1.5 23 <- 192.168.1.1 54224 57 in.telnetd 0 20893 192.168.1.5 23 -> 192.168.1.1 54224 54 in.telnetd [...]
tcptop display top TCP network packets by process. This captures traffic of newly created TCP connections that were established while this program was running. It can help identify which processes is causing TCP traffic. Full example. first release. check for updates.
# tcptop -C 30 Sampling... Please wait. 2005 Jul 5 05:18:56, load: 1.07, TCPin: 3 Kb, TCPout: 112 Kb UID PID LADDR LPORT RADDR RPORT SIZE NAME 0 242 192.168.1.5 79 192.168.1.1 54283 272 inetd 0 242 192.168.1.5 23 192.168.1.1 54284 294 inetd 0 20929 192.168.1.5 79 192.168.1.1 54283 714 in.fingerd 100 20926 192.168.1.5 36409 192.168.1.1 79 1160 finger 100 20927 192.168.1.5 36410 192.168.1.1 79 1160 finger 100 20928 192.168.1.5 36411 192.168.1.1 23 1627 telnet 0 20313 192.168.1.5 22 192.168.1.1 54285 2798 sshd 0 20931 192.168.1.5 23 192.168.1.1 54284 4622 in.telnetd 100 20941 192.168.1.5 858 192.168.1.1 514 115712 rcp 2005 Jul 5 05:19:26, load: 1.04, TCPin: 0 Kb, TCPout: 4 Kb UID PID LADDR LPORT RADDR RPORT SIZE NAME 100 20942 192.168.1.5 36412 192.168.1.1 79 1160 finger 0 20931 192.168.1.5 23 192.168.1.1 54284 7411 in.telnetd [...]
udpsnoop.d snoop UDP network I/O by process. This analyses UCP network I/O and prints the responsible PID and UID, plus standard details such as IP address and port. This tracks UDP read/writes by payload. Full example. first release! check for updates.
# udpsnoop.d UID PID LADDR LPORT DR RADDR RPORT SIZE CMD 0 27127 192.168.1.5 35534 -> 192.168.1.1 53 29 nslookup 0 27127 192.168.1.5 35534 <- 192.168.1.1 53 181 nslookup 1 221 192.168.1.5 111 <- 192.168.1.1 37524 56 rpcbind 1 221 192.168.1.5 111 -> 192.168.1.1 37524 28 rpcbind 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 40 rpc.sprayd 0 27128 192.168.1.5 35116 -> 192.168.1.1 37524 24 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 44 rpc.sprayd 0 27128 192.168.1.5 35116 <- 192.168.1.1 37524 40 rpc.sprayd 0 27128 192.168.1.5 35116 -> 192.168.1.1 37524 36 rpc.sprayd ^C
connections snoop inbound TCP connections as they are established, displaying the server process that accepted the connection. Full example is here.
# connections UID PID CMD TYPE PORT IP_SOURCE 0 242 inetd tcp 79 192.168.1.1 0 359 sshd tcp 22 192.168.1.1 100 1532 Xorg tcp 6000 192.168.1.1 ^C
prustat This displays %CPU, %Mem, %Disk and %Net utilisation by process. To examine all four key performance areas by process in Solaris was prohibitivly difficult without DTrace. prustat also uses Perl, Kstat and the procfs structures from /proc/*/*. . Full example.
# prustat -t5 5 PID %CPU %Mem %Disk %Net COMM 22301 65.01 3.17 0.00 0.00 setiathome 440 8.91 45.39 0.00 0.00 Xsun 2618 0.33 14.34 0.00 0.00 mozilla-bin 582 4.01 2.16 0.00 0.00 gnome-terminal 574 1.80 1.31 0.00 0.00 metacity PID %CPU %Mem %Disk %Net COMM 22694 3.74 0.20 74.47 0.00 tar 22301 66.70 3.17 0.00 0.00 setiathome 440 6.67 45.39 0.00 0.00 Xsun 2618 0.33 14.34 0.00 0.00 mozilla-bin 22693 3.81 1.50 0.00 0.00 dtrace PID %CPU %Mem %Disk %Net COMM 22301 63.72 3.17 0.00 0.00 setiathome 440 8.14 45.39 0.00 0.00 Xsun 22694 6.47 0.20 36.47 0.00 tar 22698 0.00 0.00 6.88 22.43 rcp 2618 0.34 14.34 0.00 0.00 mozilla-bin ^C
dtruss This is a DTrace version of truss, designed to be less of a burden and safer than truss. In the below example, dtruss examines all processes named "bash" and prints out regular truss output plus elapsed and overhead times. See the full example.
# dtruss -eon bash PID/LWP ELAPSD OVERHD SYSCALL(args) = return 3911/1: 41 26 write(0x2, "l\0", 0x1) = 1 0 3911/1: 1001579 43 read(0x0, "s\0", 0x1) = 1 0 3911/1: 38 26 write(0x2, "s\0", 0x1) = 1 0 3911/1: 1019129 43 read(0x0, " \001\0", 0x1) = 1 0 3911/1: 38 26 write(0x2, " \0", 0x1) = 1 0 3911/1: 998533 43 read(0x0, "-\0", 0x1) = 1 0 3911/1: 38 26 write(0x2, "-\001\0", 0x1) = 1 0 3911/1: 1094323 42 read(0x0, "l\0", 0x1) = 1 0 3911/1: 39 27 write(0x2, "l\001\0", 0x1) = 1 0 3911/1: 1210496 44 read(0x0, "\r\0", 0x1) = 1 0 [...]
procsystime This program provides process system call details such as elapsed time from entry to return, overhead time for CPU time consumed, and counts. In the example below we examine "ssh" processes. Full example.
# procsystime -a -n ssh Hit Ctrl-C to stop sampling... ^C Elapsed Times for process ssh, SYSCALL TIME (ns) read 295392 write 622903 pollsys 1030310531 CPU Times for process ssh, SYSCALL TIME (ns) read 183515 write 534289 pollsys 650729 Syscall Counts for process ssh, SYSCALL COUNT read 12 write 12 pollsys 24
hotuser Sample on-CPU user-level functions and libraries. This samples at 1000 Hertz, for a simple yet effective user-level profiling tool. The output will identify which function is on the CPU the most - which is the hottest. The following examples show hotuser analysing gunzip and gzip. Full example.
# ./hotuser -c 'gunzip contents.gz' Sampling... Hit Ctrl-C to end. FUNCTION COUNT PCNT libc.so.1`_free_unlocked 1 0.1% gunzip`unzip 1 0.1% ld.so.1`strcmp 1 0.1% gunzip`inflate_dynamic 1 0.1% libc.so.1`_write 1 0.1% gunzip`write_buf 1 0.1% gunzip`0x2d990 2 0.3% libc.so.1`write 2 0.3% gunzip`0x2d994 2 0.3% ld.so.1`rtld_db_preinit 3 0.4% gunzip`0x2d98c 7 0.9% gunzip`huft_build 9 1.2% libc_psr.so.1`memcpy 138 18.5% gunzip`inflate_codes 233 31.2% gunzip`updcrc 344 46.1% # ./hotuser -lc 'gzip contents' Sampling... Hit Ctrl-C to end. LIBRARY COUNT PCNT libc.so.1 2 0.0% libc_psr.so.1 37 0.9% gzip 4113 99.1%
hotkernel Sample on-CPU kernel-level functions and modules. This samples at 1000 Hertz, for a simple yet effective modules-level profiling tool. The output will identify which function is on the CPU the most - which is the hottest. The following examples show hotkernel analyse an x86 kernel. Full example.
# ./hotkernel Sampling... Hit Ctrl-C to end. ^C FUNCTION COUNT PCNT unix`swtch 1 0.1% pcplusmp`apic_redistribute_compute 1 0.1% genunix`strrput 1 0.1% unix`sys_call 1 0.1% genunix`fsflush_do_pages 1 0.1% TS`ts_wakeup 1 0.1% genunix`callout_schedule_1 1 0.1% unix`page_create_putback 1 0.1% unix`mutex_enter 4 0.3% unix`cpu_halt 1575 99.2% # ./hotkernel -m Sampling... Hit Ctrl-C to end. ^C MODULE COUNT PCNT usbms 1 0.0% specfs 1 0.0% uhci 1 0.0% sockfs 2 0.0% genunix 28 0.6% unix 4539 99.3%
dapptrace This traces user and library function usage. This is similar to the "apptrace" command, however can fetch extra details such as function elapsed times and on-cpu times. Below is a demonstration of running dapptrace on the banner command, the user function calls are being traced. Full example.
# dapptrace -eoF banner hi # # # # # # ###### # # # # # # # # # # ELAPSD CPU CALL(args) = return . . -> __fsr(0x2, 0x8047D7C, 0x8047D88) 41 4 <- __fsr = 122 . . -> main(0x2, 0x8047D7C, 0x8047D88) . . -> banner(0x8047E3B, 0x80614C2, 0x8047D38) . . -> banset(0x20, 0x80614C2, 0x8047DCC) 29 6 <- banset = 36 . . -> convert(0x68, 0x8047DCC, 0x2) 26 3 <- convert = 319 . . -> banfil(0x8061412, 0x80614C2, 0x8047DCC) 25 2 <- banfil = 57 . . -> convert(0x69, 0x8047DCC, 0x2) 23 1 <- convert = 319 . . -> banfil(0x8061419, 0x80614CA, 0x8047DCC) 23 1 <- banfil = 57 309 28 <- banner = 118 . . -> banprt(0x80614C2, 0x8047D38, 0xD27FB824) 349 322 <- banprt = 74
dappprof This profiles user and library function usage. This is a companion to dapptrace, where summary data is printed rather than a snoop of events. Below is a demonstration of running dappprof on the banner command. Full example.
# dappprof -ceoT banner hello # # ###### # # #### # # # # # # # ###### ##### # # # # # # # # # # # # # # # # # # # # ###### ###### ###### #### CALL COUNT __fsr 1 main 1 banprt 1 banner 1 banset 1 convert 5 banfil 5 TOTAL: 15 CALL ELAPSED banset 38733 banfil 150280 convert 152113 banner 907212 __fsr 1695068 banprt 1887674 TOTAL: 4831080 CALL CPU banset 7710 convert 9566 banfil 11931 __fsr 15199 banner 52685 banprt 776429 TOTAL: 873520
dvmstat This program provides vmstat like data for one particular PID, a process name, or when running a command. It prints statistics every second. Here we monitor a "find" processes, and can clearly see it exhaust the cache (dropping "re" reclaims), and then defer to disk (increasing "maj" major faults and "fpi" filesystem pageins). Full example.
# dvmstat -n find re maj mf fr epi epo api apo fpi fpo sy 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 6336 0 372 0 0 0 0 0 0 0 22255 1624 0 0 0 0 0 0 0 0 0 5497 2292 0 0 0 0 0 0 0 0 0 7715 13064 0 0 0 0 0 0 0 0 0 43998 7972 168 0 0 0 0 0 0 168 0 38361 468 636 0 0 0 0 0 0 636 0 13774 376 588 0 0 0 0 0 0 588 0 10723 80 636 0 0 0 0 0 0 656 0 11078 48 772 0 0 0 0 0 0 812 0 9841 16 1028 0 0 0 0 0 0 1056 0 10752 0 1712 0 0 0 0 0 0 1740 0 12176 4 1224 0 0 0 0 0 0 1236 0 9024
topsyscall This program continually prints a report of the top system calls, and refreshes the display every 1 second or as specified. Full example.
2005 Jun 14 02:26:40, load average: 0.16, 0.18, 0.21 syscalls: 1381 SYSCALL COUNT waitsys 5 getuid 5 xstat 7 munmap 7 brk 8 sysconfig 8 open 8 getpid 9 close 9 resolvepath 10 setcontext 18 setitimer 25 mmap 26 lwp_sigmask 32 lwp_park 41 write 78 read 78 sigaction 113 pollsys 318 ioctl 526
shellsnoop captures the text input and output live from shells running on the system. In this example shellsnoop was run in one window, while in another several commands were run: date, cal and uname -a. (this is like a simple version of ttywatcher). Full example is here.
# shellsnoop PID PPID CMD DIR TEXT 4724 3762 ksh R 4724 3762 ksh W date 4741 4724 date W Sun Mar 28 23:10:06 EST 2004 4724 3762 ksh R 4724 3762 ksh W jupiter:/etc/init.d> 4724 3762 ksh R 4724 3762 ksh R 4724 3762 ksh W cal 4742 4724 cal W March 2004 4742 4724 cal W S M Tu W Th F S 4742 4724 cal W 1 2 3 4 5 6 4742 4724 cal W 7 8 9 10 11 12 13 4742 4724 cal W 14 15 16 17 18 19 20 4742 4724 cal W 21 22 23 24 25 26 27 4742 4724 cal W 28 29 30 31 4742 4724 cal W 4724 3762 ksh R 4724 3762 ksh W jupiter:/etc/init.d> 4724 3762 ksh R 4724 3762 ksh R 4724 3762 ksh W uname -a 4743 4724 uname W SunOS jupiter 5.10 s10_51 i86pc i386 i86pc 4724 3762 ksh R
kill.d This simple DTrace program watches who is sending signals to processes. In the example below, the bash shell successfully sent a "kill -2" (SIGINT) to PID 3117, and failed to send a "kill -9" (SIGKILL) to process 12345,
# kill.d FROM COMMAND SIG TO RESULT 2344 bash 2 3117 0 2344 bash 9 12345 -1 ^C
errinfo reports on system call failures with full errno details to help explain why these errors occured. It has two styles of output: a "snoop" style to watch events (the default), and a "count" style to provide a summary (-c). Both are demonstrated below, Full example.
# errinfo EXEC SYSCALL ERR DESC gnome-netstatus- ioctl 12 Not enough core mozilla-bin lwp_park 62 timer expired Xorg read 11 Resource temporarily unavailable Xorg pollsys 4 interrupted system call mozilla-bin lwp_park 62 timer expired mozilla-bin lwp_park 62 timer expired Xorg read 11 Resource temporarily unavailable ^C # errinfo -c Sampling... Hit Ctrl-C to end. ^C EXEC SYSCALL ERR COUNT DESC gnome-netstatus- ioctl 12 1 Not enough core miniserv.pl waitsys 10 1 No children gnome-settings-d read 11 1 Resource temporarily unavailable metacity read 11 1 Resource temporarily unavailable gnome-panel read 11 1 Resource temporarily unavailable nautilus read 11 1 Resource temporarily unavailable dsdm read 11 2 Resource temporarily unavailable soffice.bin read 11 2 Resource temporarily unavailable java_vm lwp_cond_wait 62 4 timer expired svc.startd portfs 62 5 timer expired Xorg pollsys 4 15 interrupted system call Xorg read 11 26 Resource temporarily unavailable mozilla-bin lwp_park 62 58 timer expired
sshkeysnoop.d captures the keystrokes from ssh client commands running on the same server. Although the password is clearly visible, this is not a security problem with Solaris 10 rather a demonstration of the power of DTrace. Full example.
# sshkeysnoop.d UID PID PPID TYPE TEXT 100 9651 8600 cmd ssh -l fred mars 100 9651 8600 key f 100 9651 8600 key r 100 9651 8600 key e 100 9651 8600 key d 100 9651 8600 key 1 100 9651 8600 key 2 100 9651 8600 key 3 100 9651 8600 key [...]
shortlived.d This simple DTrace program measures how much time is consumed by short lived processes. This would normally be difficult to spot using sampling tools like prstat. In the example below, many short lived "expr" commands actually consume around 45% of the CPU. Full example here.
# shortlived.d Sampling.. Hit Ctrl-C to stop. ^C short lived processes: 3.394 secs total sample duration: 7.543 secs Total time by process name, ls 14 ms df 18 ms expr 3049 ms Total time by PPID, 2765 32 ms 29752 3049 ms
cputimes print CPU time consumed by Kernel/Idle/Processes. The default output prints a breakdown of cpu time into three categories, Kernel time, Idle time and time consumed by processes; all in nanoseconds. Full example.
# cputimes 1 3 2005 Apr 27 23:37:58, KERNEL 10795499 PROCESS 20941091 IDLE 970707443 2005 Apr 27 23:37:59, KERNEL 8919418 PROCESS 77446789 IDLE 910555040 2005 Apr 27 23:38:00, KERNEL 8615123 PROCESS 78314246 IDLE 810100417
cpudists print CPU time distributions by Kernel/Idle/Processes. The default output prints a cpu time usage by three categories, Kernel time, Idle time and process time. The value is the time in nanosecounds, and the count is the number of occurances. Full example.
# cpudists 5 1 2005 Apr 28 00:08:42, KERNEL value ------------- Distribution ------------- count 4096 | 0 8192 |@@@@@@@@@@@@@@@@@@@@@@@@@@@@ 1134 16384 |@@@@@@@@@ 344 32768 |@@@ 104 65536 | 3 131072 | 0 PROCESS value ------------- Distribution ------------- count 8192 | 0 16384 |@@@@@@@@@ 170 32768 |@@@@@@@@@@@@@@@@@@ 331 65536 |@@@@@@@@ 152 131072 |@ 17 262144 |@ 25 524288 |@ 13 1048576 | 4 2097152 | 0 IDLE value ------------- Distribution ------------- count 2097152 | 0 4194304 |@ 9 8388608 |@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ 418 16777216 |@@@ 31 33554432 | 0
setuids.d snoop setuid calls. This can be used to watch user logins, and "su" usage. Full example is here.
# setuids.d UID SUID PPID PID PCMD CMD 0 100 3037 3040 in.telnetd login -p -h mars -d /dev/pts/12 100 0 3040 3045 bash su - 0 102 3045 3051 sh su - fred 0 100 3055 3059 sshd /usr/lib/ssh/sshd 0 100 3065 3067 in.rlogind login -d /dev/pts/12 -r mars 0 100 3071 3073 in.rlogind login -d /dev/pts/12 -r mars 0 102 3078 3081 in.telnetd login -p -h mars -d /dev/pts/12 [...]
bitesize.d is a simple program to examine the way in which processes use the disks - are they causing large I/O operations or many small "bites"? In the example below we can see that the find command has caused mostly 1K events, while the tar command was transferring more data per operation. Full example.
# bitesize.d Sampling... Hit Ctrl-C to end. ^C PID CMD 7109 find / value ------------- Distribution ------------- count 512 | 0 1024 |@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ 1452 2048 |@@ 91 4096 | 33 8192 |@@ 97 16384 | 0 3 fsflush value ------------- Distribution ------------- count 4096 | 0 8192 |@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ 449 16384 | 0 7108 tar cf /dev/null / value ------------- Distribution ------------- count 256 | 0 512 | 70 1024 |@@@@@@@@@@ 1306 2048 |@@@@ 569 4096 |@@@@@@@@@ 1286 8192 |@@@@@@@@@@ 1403 16384 |@ 190 32768 |@@@ 396 65536 | 0 [...]
seeksize.d prints the disk head seek distance by process. This can identify whether processes are accessing the disks in a "random" or "sequential" manner. The example below illustrates sequential access. Use seeksize.d in conjunction with bitesize.d. Full example.
# seeksize.d Sampling... Hit Ctrl-C to end. ^C PID CMD 22349 scp /dl/sol-10-b63-x86-v1.iso mars: value ------------- Distribution ------------- count -1 | 0 0 |@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ 726 1 | 0 2 | 0 4 | 0 8 |@ 13 16 | 4 32 | 0 [...]
zvmstat is a DTrace version of vmstat to print info per Zone. More examples here.
# zvmstat 1 ZONE re mf fr sr epi epo epf api apo apf fpi fpo fpf global 54 316 1 0 0 0 0 0 0 0 0 1 1 workzone1 0 0 0 0 0 0 0 0 0 0 0 0 0 ZONE re mf fr sr epi epo epf api apo apf fpi fpo fpf global 157 659 1 0 10 0 0 0 0 0 3 2 1 workzone1 770 1085 0 0 48 0 0 0 0 0 928 0 0 ZONE re mf fr sr epi epo epf api apo apf fpi fpo fpf global 56 317 0 0 6 0 0 0 0 0 2 0 0 workzone1 1478 21 0 0 0 0 0 0 0 0 1635 0 0 [...]
zhostid is a DTrace daemon to change the host id to different values for each zone. More examples here.
global# ./zhostid & [1] 8717 global# hostid 12345678 global# global# zlogin workzone1 [Connected to zone 'workzone1' pts/10] Last login: Tue Jun 21 03:51:10 on pts/10 Sun Microsystems Inc. SunOS 5.10 Generic January 2005 # # hostid 90abcdef
socketsnoop.d This program snoops socket data transfer events by process, identifying which process is responsible for reading or writing data on the network. Full example.
# socketsnoop.d UID PID DIR SIZE CMD 0 19886 W 64 ssh mars 0 19886 R 80 ssh mars 0 19915 W 0 finger @mars 0 19915 W 2 finger @mars 0 19915 R 633 finger @mars 0 19915 R 0 finger @mars 0 19886 W 64 ssh mars 0 19886 R 80 ssh mars 0 19886 W 48 ssh mars 0 19886 R 80 ssh mars 100 4789 W 6 vncviewer mars:4 100 4789 R 348 vncviewer mars:4 100 4789 W 10 vncviewer mars:4 [...]
anonprofile.d is a program to snoop anonymous memory usage by process. This provides a profile of a process's anonymous memory size over time. It can assist troubleshooting memory issues during software development. More examples here.
# anonprofile.d UID PID TOTAL ARGS 0 14380 4169728 /usr/sbin/dtrace -s anonprofile.d 100 14382 4096 bash 100 14382 8192 ls -l 100 14382 12288 ls -l 100 14382 20480 ls -l 100 14382 24576 ls -l 100 14382 28672 ls -l 100 14382 57344 ls -l 100 14382 65536 ls -l 100 14382 73728 ls -l 100 14382 106496 ls -l 100 14382 110592 ls -l 100 14382 118784 ls -l 100 14382 126976 ls -l 100 14382 131072 ls -l 100 14382 135168 ls -l 100 14382 143360 ls -l [...]
intrtime Time spent by the kernel in interrupt threads was previously difficult to measure. intrtime gives a break down of the interrupt types and times spent servicing each. Full example.
# intrtime 1 Interrupt Time(ns) %Time uhci_intr 23753 0.00 ata_intr 3698089 0.37 i8042_intr 7360399 0.73 gld_intr 12319508 1.22 TOTAL(int) 23401749 2.31 TOTAL(dur) 1012546207 100.00
typewriter-0.75.tar.gz This makes your console keyboard sound like a mechanical keyboard. This is for entertainment only.
# ./ultra5.d & [1] 7660 typewriter.d running for the console keyboard. #
These are examples of performing troubleshooting using DTrace, and often begin by using DTrace at the command line before using DTrace scripts such as the tools above.
DTrace vs truss this demonstrates the performace impact of using DTrace vs truss. DTrace is designed to minimise the burden on the system while it is running.
DTracing SMC here we have a quick look at using DTrace to investigate the behaviour of SMC when it is first executed. SMC is a system administration GUI that takes a while the first time it is run as it compiles Java classes.
DTracing Lost CPU here we take a look at a mysterious problem where the CPUs are busy, but there dosen't appear to be any processes responsible for this. Where has the CPU time gone?
prstat vs top this analyses the CPU overhead of running prstat vs running top. In the past some people have suggested that top is a CPU hog - DTrace can measure it.
Several years ago, Richard McDougall wrote taztool - a GUI to display disk activity in an amazing and intuitive way. It used TNF trace data - a predecessor of DTrace. DTraceTazTool is a DTrace version of taztool. It is currently in development, and as such this is an alpha release. There are many more features to code, but it may already prove a useful tool.
The current version of DTraceTazTool is: DTaz-0.51.
The following image shows DTraceTazTool tracing the activity of a UFS file system as it was archived by the tar command. For the top plot: the requested block location is on the Y-axis, time is on the X-axis, and the colour reflects the number of requests for that location (many == red). The bottom plot shows maximum and average seek distance,
The thick red line is an indication of sequential disk activity, and the scattered blue blocks are an indication of random disk activity.
DTraceTazTool already has some tunable options, such as the size of the pixels drawn and the sample rate,
DTraceTazTool needs to either run as root, or as a user with the dtrace_kernel privilege.
# dexplorer Output dir will be the current dir (/export/home/root/DTrace/Dexplorer). Hit enter for yes, or type path: Starting dexplorer ver 0.70. Sample interval is 5 seconds. Total run is > 100 seconds. 0% Interrupts by CPU... 5% Interrupt counts... 10% Dispatcher queue length by CPU... 15% Sdt counts... 20% Pages paged in by process name... 25% Files opened count... 30% Disk I/O size distribution by process name... 35% Minor faults by process name... 40% Vminfo data by process name... 45% Mib data by mib statistic... 50% TCP write bytes by process... 55% Sample process @ 1000 Hz... 60% Syscall count by process name... 65% Syscall count by syscall... 70% Read bytes by process name... 75% Write bytes by process name... 80% Sysinfo counts by process name... 85% New process counts with arguments... 90% Signal counts... 95% Syscall error counts... 100% Done. File is de_jupiter_200506271803.tar.gz # # ls -l de_jupiter_200506271803.tar.gz -rw-r--r-- 1 root root 6346 Jun 27 18:05 de_jupiter_200506271803.tar.gz
The output file can be useful to send to other people for analysis.
Books:
Other DTrace scripts:
External DTrace links:
Brendan's site:
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