Linux: How to measure actual memory usage of an application or process?

Question

How do you measure the memory usage of an application or process in Linux?

From the blog article of Understanding memory usage on Linux, "ps" is not an accurate tool to use for this intent.

Why ps is "wrong"

Depending on how you look at it, ps is not reporting the real memory usage of processes. What it is really doing is showing how much real memory each process would take up if it were the only process running. Of course, a typical Linux machine has several dozen processes running at any given time, which means that the VSZ and RSS numbers reported by ps are almost definitely "wrong".

Answer 1

With ps or similiar tools you will only get the amount of memory pages allocated by that process. This number is correct, but:

a) does not reflect the actual amount of memory used by the application, only the amount of memory reserved for it

b) can be misleading if pages are shared, for example by several threads or by using dynamically linked libraries

If you really want to know what amount of memory your application actually uses, you need to run it within a profiler. For example, valgrind can give you insights about the amount of memory used, and, more importantly, about possible memory leaks in your program.

Answer 2

Hard to tell for sure, but here are two "close" things that can help.

$ ps aux 

will give you Virtual Size (VSZ)

You can also get detailed stats from /proc filesystem by going to /proc/$pid/status

The most important is the VmSize, which should be close to what "ps aux" gives.

/proc/19420$ cat status
Name:   firefox
State:  S (sleeping)
Tgid:   19420
Pid:    19420
PPid:   1
TracerPid:  0
Uid:    1000	1000	1000	1000
Gid:    1000	1000	1000	1000
FDSize: 256
Groups: 4 6 20 24 25 29 30 44 46 107 109 115 124 1000 
VmPeak:   222956 kB
VmSize:   212520 kB
VmLck:         0 kB
VmHWM:    127912 kB
VmRSS:    118768 kB
VmData:   170180 kB
VmStk:       228 kB
VmExe:        28 kB
VmLib:     35424 kB
VmPTE:       184 kB
Threads:    8
SigQ:   0/16382
SigPnd: 0000000000000000
ShdPnd: 0000000000000000
SigBlk: 0000000000000000
SigIgn: 0000000020001000
SigCgt: 000000018000442f
CapInh: 0000000000000000
CapPrm: 0000000000000000
CapEff: 0000000000000000
Cpus_allowed:   03
Mems_allowed:   1
voluntary_ctxt_switches:    63422
nonvoluntary_ctxt_switches: 7171

Answer 3

In recent versions of linux, use the smaps subsystem. For example, for a process with a PID of 1234:

cat /proc/1234/smaps

It will tell you exactly how much memory it is using at that time. More importantly, it will divide the memory into private and shared, so you can tell how much memory your instance of the program is using, without including memory shared between multiple instances of the program.

Answer 4

Try the pmap command:

pmap -x <process pid>

Answer 5

There is no easy way to calculate this. But some people have tried to get some good answers: ps_mem.py

ps_mem.py at github

Answer 6

This is an excellent summary of the tools and problems: archive.org link

I'll quote it, so that more devs will actually read it.

If you want to analyse memory usage of the whole system or to thoroughly analyse memory usage of one application (not just its heap usage), use exmap. For whole system analysis, find processes with the highest effective usage, they take the most memory in practice, find processes with the highest writable usage, they create the most data (and therefore possibly leak or are very ineffective in their data usage). Select such application and analyse its mappings in the second listview. See exmap section for more details. Also use xrestop to check high usage of X resources, especially if the process of the X server takes a lot of memory. See xrestop section for details.

If you want to detect leaks, use valgrind or possibly kmtrace.

If you want to analyse heap (malloc etc.) usage of an application, either run it in memprof or with kmtrace, profile the application and search the function call tree for biggest allocations. See their sections for more details.

Answer 7

There isn't a single answer for this because you can't pin point precisely the amount of memory a process uses. Most processes under linux use shared libraries. For instance, let's say you want to calculate memory usage for the 'ls' process. Do you count only the memory used by the executable 'ls' ( if you could isolate it) ? How about libc? Or all these other libs that are required to run 'ls'?

linux-gate.so.1 =>  (0x00ccb000)
librt.so.1 => /lib/librt.so.1 (0x06bc7000)
libacl.so.1 => /lib/libacl.so.1 (0x00230000)
libselinux.so.1 => /lib/libselinux.so.1 (0x00162000)
libc.so.6 => /lib/libc.so.6 (0x00b40000)
libpthread.so.0 => /lib/libpthread.so.0 (0x00cb4000)
/lib/ld-linux.so.2 (0x00b1d000)
libattr.so.1 => /lib/libattr.so.1 (0x00229000)
libdl.so.2 => /lib/libdl.so.2 (0x00cae000)
libsepol.so.1 => /lib/libsepol.so.1 (0x0011a000)

You could argue that they are shared by other processes, but 'ls' can't be run on the system without them being loaded.

Also, if you need to know how much memory a process needs in order to do capacity planning, you have to calculate how much each additional copy of the process uses. I think /proc/PID/status might give you enough info of the memory usage AT a single time. On the other hand, valgrind will give you a better profile of the memory usage throughout the lifetime of the program

Answer 8

Use smem, which is an alternative to ps which calculates the USS and PSS per process.

• USS - Unique Set Size. This is the amount of unshared memory unique to that process (think of it as unique memory). It does not include shared memory. Thus this will under-report the amount of memory a process uses, but is helpful when you want to ignore shared memory.

• PSS - Proportional Set Size. This is what you want. It adds together the unique memory (USS), along with a proportion of its shared memory divided by the number of other processes sharing that memory. Thus it will give you an accurate representation of how much actual physical memory is being used per process - with shared memory truly represented as shared. Think of it as physical memory.

How this compares to RSS as reported by ps and other utilties:

• RSS - Resident Set Size. This is the amount of shared memory plus unshared memory used by each process. If any processes share memory, this will over-report the amount of memory actually used, because the same shared memory will be counted more than once - appearing again in each other process that shares the same memory. Thus it is fairly unreliable, especially when high-memory processes have a lot of forks.

Notice: smem can also (optionally) output graphs such as pie charts and the like. IMO you don't need any of that. If you just want to use it from the command line like you might use ps -A v, then you don't need to install the python-matplotlib recommended dependency.

Answer 9

If your code is in C or C++ you might be able to use getrusage() which returns you various statistics about memory and time usage of your process.

Not all platforms support this though and will return 0 values for the memory-use options.

Instead you can look at the virtual file created in /proc/[pid]/statm (where [pid] is replaced by your process id. You can obtain this from getprocessid()).

This file will look like a text file with 7 integers. You are probably most interested in the first (all memory use) and sixth (data memory use) numbers in this file.

Answer 10

If you want something quicker than profiling with Valgrind and your kernel is older and you can't use smaps, a ps with the options to show the resident set of the process (with "ps -o rss,command") can give you a quick and reasonable aproximation of the real amount of non-swapped memory being used.

Answer 11

A good test of the more "real world" usage is to open the application, then run "vmstat -s" and check the "active memory" statistic. Close the application, wait a few seconds and run "vmstat -s" again. However much active memory was freed was in evidently in use by the app.

Answer 12

Valgrind can show detailed information but it slows down the target application significantly, and most of the time it changes the behavior of the app.
Exmap was something I didn't know yet, but it seems that you need a kernel module to get the information, which can be an obstacle.

I assume what everyone wants to know WRT "memory usage" is the following...
In linux, the amount of physical memory a single process might use can be roughly divided into following categories.

• M.a anonymous mapped memory

  • .p private
    • .d dirty == malloc/mmapped heap and stack allocated and written memory
    • .c clean == malloc/mmapped heap and stack memory once allocated, written, then freed, but not reclaimed yet
  • .s shared
    • .d dirty == malloc/mmaped heap could get copy-on-write and shared among processes (edited)
    • .c clean == malloc/mmaped heap could get copy-on-write and shared among processes (edited)

• M.n named mapped memory

  • .p private
    • .d dirty == file mmapped written memory private
    • .c clean == mapped program/library text private mapped
  • .s shared
    • .d dirty == file mmapped written memory shared
    • .c clean == mapped library text shared mapped

Utility included in Android called showmap is quite useful

virtual                    shared   shared   private  private
size     RSS      PSS      clean    dirty    clean    dirty    object
-------- -------- -------- -------- -------- -------- -------- ------------------------------
       4        0        0        0        0        0        0 0:00 0                  [vsyscall]
       4        4        0        4        0        0        0                         [vdso]
      88       28       28        0        0        4       24                         [stack]
      12       12       12        0        0        0       12 7909                    /lib/ld-2.11.1.so
      12        4        4        0        0        0        4 89529                   /usr/lib/locale/en_US.utf8/LC_IDENTIFICATION
      28        0        0        0        0        0        0 86661                   /usr/lib/gconv/gconv-modules.cache
       4        0        0        0        0        0        0 87660                   /usr/lib/locale/en_US.utf8/LC_MEASUREMENT
       4        0        0        0        0        0        0 89528                   /usr/lib/locale/en_US.utf8/LC_TELEPHONE
       4        0        0        0        0        0        0 89527                   /usr/lib/locale/en_US.utf8/LC_ADDRESS
       4        0        0        0        0        0        0 87717                   /usr/lib/locale/en_US.utf8/LC_NAME
       4        0        0        0        0        0        0 87873                   /usr/lib/locale/en_US.utf8/LC_PAPER
       4        0        0        0        0        0        0 13879                   /usr/lib/locale/en_US.utf8/LC_MESSAGES/SYS_LC_MESSAGES
       4        0        0        0        0        0        0 89526                   /usr/lib/locale/en_US.utf8/LC_MONETARY
       4        0        0        0        0        0        0 89525                   /usr/lib/locale/en_US.utf8/LC_TIME
       4        0        0        0        0        0        0 11378                   /usr/lib/locale/en_US.utf8/LC_NUMERIC
    1156        8        8        0        0        4        4 11372                   /usr/lib/locale/en_US.utf8/LC_COLLATE
     252        0        0        0        0        0        0 11321                   /usr/lib/locale/en_US.utf8/LC_CTYPE
     128       52        1       52        0        0        0 7909                    /lib/ld-2.11.1.so
    2316       32       11       24        0        0        8 7986                    /lib/libncurses.so.5.7
    2064        8        4        4        0        0        4 7947                    /lib/libdl-2.11.1.so
    3596      472       46      440        0        4       28 7933                    /lib/libc-2.11.1.so
    2084        4        0        4        0        0        0 7995                    /lib/libnss_compat-2.11.1.so
    2152        4        0        4        0        0        0 7993                    /lib/libnsl-2.11.1.so
    2092        0        0        0        0        0        0 8009                    /lib/libnss_nis-2.11.1.so
    2100        0        0        0        0        0        0 7999                    /lib/libnss_files-2.11.1.so
    3752     2736     2736        0        0      864     1872                         [heap]
      24       24       24        0        0        0       24 [anon]
     916      616      131      584        0        0       32                         /bin/bash
-------- -------- -------- -------- -------- -------- -------- ------------------------------
   22816     4004     3005     1116        0      876     2012 TOTAL

Answer 13

I'm using htop, it's very good console program similar to Windows Task Manager.

Answer 14

Valgrind is amazing if you have the time to run it. valgrind --tool=massif is The Right Solution.

However, I'm starting to run larger examples, and using valgrind is no longer practical. Is there a way to tell the maximum memory usage (modulo page size and shared pages) of a program?

On a real unix system, /usr/bin/time -v works. On linux, however, this does /not/ work.

Answer 15

#!/bin/ksh
#
# Returns total memory used by process $1 in kb.
#
# See /proc/NNNN/smaps if you want to do something
# more interesting.
#

IFS=$'\n'

for line in $(</proc/$1/smaps)
do
   [[ $line =~ ^Size:\s+(\S+) ]] && ((kb += ${.sh.match[1]}))
done

print $kb

Answer 16

Get valgrind. give it your program to run, and it'll tell you plenty about its memory usage.

This would apply only for the case of a program that runs for some time and stops. I don't know if valgrind can get its hands on an already-running process or shouldn't-stop processes such as daemons.

Answer 17

Below command line will give you the total memory used by the various process running on the Linux machine in MB

ps -eo size,pid,user,command --sort -size | awk '{ hr=$1/1024 ; printf("%13.2f Mb ",hr) } { for ( x=4 ; x<=NF ; x++ ) { printf("%s ",$x) } print "" }' | awk '{total=total + $1} END {print total}'

Answer 18

If the process is not using up to much memory (either because you expect this to be the case, or some other command has given this initial indication), and the process can withstand being stopped for a short period of time, you can try to use the gcore command.

gcore <pid>

Check the size of the generated core file to get a good idea how much memory a particular process is using.

This won't work to well if process is using hundreds of megs, or gigs, as the core generation could take several seconds or minutes to be created depending on I/O performance. During the core creation the process is stopped (or "frozen") to prevent memory changes. So be careful.

Also make sure the mount point where the core is generated has plenty of disk space and that the system will not react negatively to the core file being created in that particular directory.

Answer 19

Another vote for valgrind here, but I would like to add that you can use a tool like Alleyoop to help you interpret the results generated by valgrind.

I use the two tools all the time and always have lean, non-leaky code to proudly show for it ;)