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Criteria和Detachedcriteria的区别及应用 -
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This entry is for those people who have ever wondered, "Why the hell is
a simple KDE text editor taking up 25 megabytes of memory?" Many people
are led to believe that many Linux applications, especially KDE or
Gnome programs, are "bloated" based solely upon what tools like ps
report. While this may or may not be true, depending on the program, it
is not generally true -- many programs are much more memory efficient
than they seem.
What ps reports
The ps tool can output various pieces of information about a process,
such as its process id, current running state, and resource
utilization. Two of the possible outputs are VSZ and RSS, which stand
for "virtual set size" and "resident set size", which are commonly used
by geeks around the world to see how much memory processes are taking
up.
For example, here is the output of ps aux for KEdit on my computer:
USER PID %CPU %MEM VSZ RSS TTY STAT START TIME COMMAND
dbunker 3468 0.0 2.7 25400 14452 ? S 20:19 0:00 kdeinit: kedit
According to ps, KEdit has a virtual size of about 25 megabytes and a
resident size of about 14 megabytes (both numbers above are reported in
kilobytes). It seems that most people like to randomly choose to accept
one number or the other as representing the real memory usage of a
process. I'm not going to explain the difference between VSZ and RSS
right now but, needless to say, this is the wrong approach; neither
number is an accurate picture of what the memory cost of running KEdit
is.
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". In order to understand why, it is
necessary to learn how Linux handles shared libraries in programs.
Most major programs on Linux use shared libraries to facilitate certain
functionality. For example, a KDE text editing program will use several
KDE shared libraries (to allow for interaction with other KDE
components), several X libraries (to allow it to display images and
copy and pasting), and several general system libraries (to allow it to
perform basic operations). Many of these shared libraries, especially
commonly used ones like libc, are used by many of the programs running
on a Linux system. Due to this sharing, Linux is able to use a great
trick: it will load a single copy of the shared libraries into memory
and use that one copy for every program that references it.
For better or worse, many tools don't care very much about this very
common trick; they simply report how much memory a process uses,
regardless of whether that memory is shared with other processes as
well. Two programs could therefore use a large shared library and yet
have its size count towards both of their memory usage totals; the
library is being double-counted, which can be very misleading if you
don't know what is going on.
Unfortunately, a perfect representation of process memory usage isn't
easy to obtain. Not only do you need to understand how the system
really works, but you need to decide how you want to deal with some
hard questions. Should a shared library that is only needed for one
process be counted in that process's memory usage? If a shared library
is used my multiple processes, should its memory usage be evenly
distributed among the different processes, or just ignored? There isn't
a hard and fast rule here; you might have different answers depending
on the situation you're facing. It's easy to see why ps doesn't try
harder to report "correct" memory usage totals, given the ambiguity.
Seeing a process's memory map
Enough talk; let's see what the situation is with that "huge" KEdit
process. To see what KEdit's memory looks like, we'll use the pmap
program (with the -d flag):
Address Kbytes Mode Offset Device Mapping
08048000 40 r-x-- 0000000000000000 0fe:00000 kdeinit
08052000 4 rw--- 0000000000009000 0fe:00000 kdeinit
08053000 1164 rw--- 0000000008053000 000:00000 [ anon ]
40000000 84 r-x-- 0000000000000000 0fe:00000 ld-2.3.5.so
40015000 8 rw--- 0000000000014000 0fe:00000 ld-2.3.5.so
40017000 4 rw--- 0000000040017000 000:00000 [ anon ]
40018000 4 r-x-- 0000000000000000 0fe:00000 kedit.so
40019000 4 rw--- 0000000000000000 0fe:00000 kedit.so
40027000 252 r-x-- 0000000000000000 0fe:00000 libkparts.so.2.1.0
40066000 20 rw--- 000000000003e000 0fe:00000 libkparts.so.2.1.0
4006b000 3108 r-x-- 0000000000000000 0fe:00000 libkio.so.4.2.0
40374000 116 rw--- 0000000000309000 0fe:00000 libkio.so.4.2.0
40391000 8 rw--- 0000000040391000 000:00000 [ anon ]
40393000 2644 r-x-- 0000000000000000 0fe:00000 libkdeui.so.4.2.0
40628000 164 rw--- 0000000000295000 0fe:00000 libkdeui.so.4.2.0
40651000 4 rw--- 0000000040651000 000:00000 [ anon ]
40652000 100 r-x-- 0000000000000000 0fe:00000 libkdesu.so.4.2.0
4066b000 4 rw--- 0000000000019000 0fe:00000 libkdesu.so.4.2.0
4066c000 68 r-x-- 0000000000000000 0fe:00000 libkwalletclient.so.1.0.0
4067d000 4 rw--- 0000000000011000 0fe:00000 libkwalletclient.so.1.0.0
4067e000 4 rw--- 000000004067e000 000:00000 [ anon ]
4067f000 2148 r-x-- 0000000000000000 0fe:00000 libkdecore.so.4.2.0
40898000 64 rw--- 0000000000219000 0fe:00000 libkdecore.so.4.2.0
408a8000 8 rw--- 00000000408a8000 000:00000 [ anon ]
... (trimmed) ...
mapped: 25404K writeable/private: 2432K shared: 0K
I cut out a lot of the output; the rest is similar to what is shown.
Even without the complete output, we can see some very interesting
things. One important thing to note about the output is that each
shared library is listed twice; once for its code segment and once for
its data segment. The code segments have a mode of "r-x--", while the
data is set to "rw---". The Kbytes, Mode, and Mapping columns are the
only ones we will care about, as the rest are unimportant to the
discussion.
If you go through the output, you will find that the lines with the
largest Kbytes number are usually the code segments of the included
shared libraries (the ones that start with "lib" are the shared
libraries). What is great about that is that they are the ones that can
be shared between processes. If you factor out all of the parts that
are shared between processes, you end up with the "writeable/private"
total, which is shown at the bottom of the output. This is what can be
considered the incremental cost of this process, factoring out the
shared libraries. Therefore, the cost to run this instance of KEdit
(assuming that all of the shared libraries were already loaded) is
around 2 megabytes. That is quite a different story from the 14 or 25
megabytes that ps reported.
What does it all mean?
The moral of this story is that process memory usage on Linux is a
complex matter; you can't just run ps and know what is going on. This
is especially true when you deal with programs that create a lot of
identical children processes, like Apache. ps might report that each
Apache process uses 10 megabytes of memory, when the reality might be
that the marginal cost of each Apache process is 1 megabyte of memory.
This information becomes critial when tuning Apache's MaxClients
setting, which determines how many simultaneous requests your server
can handle (although see one of my past postings for another way of
increasing Apache's performance).
It also shows that it pays to stick with one desktop's software as much
as possible. If you run KDE for your desktop, but mostly use Gnome
applications, then you are paying a large price for a lot of redundant
(but different) shared libraries. By sticking to just KDE or just Gnome
apps as much as possible, you reduce your overall memory usage due to
the reduced marginal memory cost of running new KDE or Gnome
applications, which allows Linux to use more memory for other
interesting things (like the file cache, which speeds up file accesses
immensely).
发表评论
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redhat as5.4 安装网站截图软件CutyCapt
2012-02-23 09:21 2080先安装Qt47 Java代码 收藏代码 增加qt4 ... -
linux中将前台进程转入后台的方法
2011-09-07 17:31 2764今天在网上偶然看到一个不错的建议。先更新一下: 以前在使用no ... -
Vnstat: 简单实用的网络流量统计工具
2011-05-18 22:02 1468http://www.linuxeden.com/html/s ... -
视频网站架构
2011-01-23 01:01 1582http://www.doorsolutions.cn/ 概述 ... -
how to install ffmpeg
2011-01-23 00:33 1540A little while back, I posted a ... -
CentOS安装MPlayer
2010-05-31 14:36 1506http://wiki.centos.org/TipsAndT ... -
linux下tomcat启动80端口不能访问的问题
2009-06-15 21:18 7068service iptables save [code=&a ... -
上传文件到linux时出现的乱码
2009-04-30 16:32 2125遇到见很郁闷的事。 维护一个很老的代码,编码都是gbk的,别 ... -
gdb 使用手册
2009-04-28 16:46 2095简述 一 列文件清单 二 ... -
OOM 机制
2009-03-26 21:40 1220When a system runs out of memor ... -
OOM killer "Out of Memory: Killed process SOLUTION
2009-03-26 21:39 1858Since this problem seems to pop ... -
A Quick Benchmark: Gzip vs. Bzip2 vs. LZMA
2009-03-09 09:50 1475How the test files were selecte ... -
linux 网络配置
2009-03-03 15:54 1153网络信息查看 查看网路接口信息 1.了解lin ... -
linux下删除文件出错
2009-01-12 16:27 2086今天忘记把程序停止, ... -
linux下自动备份mysql数据库
2009-01-12 16:22 1131新建文件: vi /home/bzhang/mysql_aut ... -
计划任务工具 cron 的配置和说明
2009-01-12 10:01 1107计划任务工具 cron 的配置和说明 作者: 北南南 ... -
用vsFTPd自架Linux网络安装服务器,以及Redhat局域网安装的解决办法
2009-01-05 12:06 1310ZZ FROM: http://www.linuxsir.or ... -
Clock in a Linux Guest Runs More Slowly or Quickly
2009-01-04 10:55 2074Clock in a Linux Guest R ... -
IPTABLE 学习
2008-12-30 15:40 959To be continued... -
VSFTP的时间错误
2008-12-30 10:31 844vsftp的配置问题 /etc/vsftpd/vsftpd.c ...
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