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Performance Tuning






mod_perl Pocket Reference

mod_perl Pocket Reference

By Andrew Ford
Writing Apache Modules with Perl and C

Writing Apache Modules with Perl and C

By Lincoln Stein, Doug MacEachern
Embedding Perl in HTML with Mason

Embedding Perl in HTML with Mason

By Dave Rolsky, Ken Williams
mod_perl2 User's Guide

mod_perl2 User's Guide

By Stas Bekman, Jim Brandt
Practical mod_perl

Practical mod_perl

By Stas Bekman, Eric Cholet
The mod_perl Developer's Cookbook

The mod_perl Developer's Cookbook

By Geoffrey Young, Paul Lindner, Randy Kobes


Table of Contents

Description

An exhaustive list of various techniques you might want to use to get the most performance possible out of your mod_perl server: configuration, coding, memory use, and more.



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The Big Picture

To make the user's Web browsing experience as painless as possible, every effort must be made to wring the last drop of performance from the server. There are many factors which affect Web site usability, but speed is one of the most important. This applies to any webserver, not just Apache, so it is very important that you understand it.

How do we measure the speed of a server? Since the user (and not the computer) is the one that interacts with the Web site, one good speed measurement is the time elapsed between the moment when she clicks on a link or presses a Submit button to the moment when the resulting page is fully rendered.

The requests and replies are broken into packets. A request may be made up of several packets, a reply may be many thousands. Each packet has to make its own way from one machine to another, perhaps passing through many interconnection nodes. We must measure the time starting from when the first packet of the request leaves our user's machine to when the last packet of the reply arrives back there.

A webserver is only one of the entities the packets see along their way. If we follow them from browser to server and back again, they may travel by different routes through many different entities. Before they are processed by your server the packets might have to go through proxy (accelerator) servers and if the request contains more than one packet, packets might arrive to the server by different routes with different arrival times, therefore it's possible that some packets that arrive earlier will have to wait for other packets before they could be reassembled into a chunk of the request message that will be then read by the server. Then the whole process is repeated in reverse.

You could work hard to fine tune your webserver's performance, but a slow Network Interface Card (NIC) or a slow network connection from your server might defeat it all. That's why it's important to think about the Big Picture and to be aware of possible bottlenecks between the server and the Web.

Of course there is little that you can do if the user has a slow connection. You might tune your scripts and webserver to process incoming requests ultra quickly, so you will need only a small number of working servers, but you might find that the server processes are all busy waiting for slow clients to accept their responses.

But there are techniques to cope with this. For example you can deliver the respond after it was compressed. If you are delivering a pure text respond--gzip compression will sometimes reduce the size of the respond by 10 times.

You should analyze all the involved components when you try to create the best service for your users, and not the web server or the code that the web server executes. A Web service is like a car, if one of the parts or mechanisms is broken the car may not go smoothly and it can even stop dead if pushed too far without first fixing it.

And let me stress it again--if you want to have a success in the web service business you should start worrying about the client's browsing experience and not only how good your code benchmarks are.



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System Analysis

Before we try to solve a problem we need to identify it. In our case we want to get the best performance we can with as little monetary and time investment as possible.



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Software Requirements

Covered in the section "Choosing an Operating System".



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Hardware Requirements

(META: Only partial analysis. Please submit more points. Many points are scattered around the document and should be gathered here, to represent the whole picture. It also should be merged with the above item!)

You need to analyze all of the problem's dimensions. There are several things that need to be considered:

The first one is probably the easiest to optimize. Following the performance optimization tips in this and other documents allows a perl (mod_perl) programmer to exercise their code and improve it.

The second one is a function of RAM. How much RAM is in each box, how many boxes do you have, and how much RAM does each mod_perl process use? Multiply the first two and divide by the third. Ask yourself whether it is better to switch to another, possibly just as inefficient language or whether that will actually cost more than throwing another powerful machine into the rack.

Also ask yourself whether switching to another language will even help. In some applications, for example to link Oracle runtime libraries, a huge chunk of memory is needed so you would save nothing even if you switched from Perl to C.

The last two are important. You need a realistic estimate. Are you really expecting 8 million hits per day? What is the expected peak load, and what kind of response time do you need to guarantee? Remember that these numbers might change drastically when you apply code changes and your site becomes popular. Remember that when you get a very high hit rate, the resource requirements don't grow linearly but exponentially!

More coverage is provided in the section "Choosing Hardware".



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Essential Tools

In order to improve performance we need measurement tools. The main tool categories are benchmarking and code profiling.

It's important to understand that in a major number of the benchmarking tests that we will execute we will not look at the absolute result numbers but the relation between the two and more result sets, since in most cases we would try to show which coding approach is preferable and the you shouldn't try to compare the absolute results collected while running the same benchmarks on your machine, since you won't have the exact hardware and software setup anyway. So this kind of comparison would be misleading. Compare the relative results from the tests running on your machine, don't compare your absolute results with those in this Guide.



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Benchmarking Applications

How much faster is mod_perl than mod_cgi (aka plain perl/CGI)? There are many ways to benchmark the two. I'll present a few examples and numbers below. Check out the benchmark directory of the mod_perl distribution for more examples.

If you are going to write your own benchmarking utility, use the Benchmark module for heavy scripts and the Time::HiRes module for very fast scripts (faster than 1 sec) where you will need better time precision.

There is no need to write a special benchmark though. If you want to impress your boss or colleagues, just take some heavy CGI script you have (e.g. a script that crunches some data and prints the results to STDOUT), open 2 xterms and call the same script in mod_perl mode in one xterm and in mod_cgi mode in the other. You can use lwp-get from the LWP package to emulate the browser. The benchmark directory of the mod_perl distribution includes such an example.

See also two tools for benchmarking: ApacheBench and crashme test



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Benchmarking Perl Code

If you are going to write your own benchmarking utility, use the Benchmark module and the Time::HiRes module where you need better time precision (less than 10msec).

An example of the Benchmark.pm module usage:

  benchmark.pl
  ------------
  use Benchmark;
  
  timethis (1_000,
   sub {
    my $x = 100;
    my $y = log ($x ** 100)  for (0..10000);
  });

  % perl benchmark.pl
  timethis 1000: 25 wallclock secs (24.93 usr +  0.00 sys = 24.93 CPU)

If you want to get the benchmark results in micro-seconds you will have to use the Time::HiRes module, its usage is similar to Benchmark's.

  use Time::HiRes qw(gettimeofday tv_interval);
  my $start_time = [ gettimeofday ];
  sub_that_takes_a_teeny_bit_of_time();
  my $end_time = [ gettimeofday ];
  my $elapsed = tv_interval($start_time,$end_time);
  print "The sub took $elapsed seconds."

See also the crashme test.



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Benchmarking a Graphic Hits Counter with Persistent DB Connections

Here are the numbers from Michael Parker's mod_perl presentation at the Perl Conference (Aug, 98). (Sorry, there used to be links here to the source, but they went dead one day, so I removed them). The script is a standard hits counter, but it logs the counts into a mysql relational DataBase:

    Benchmark: timing 100 iterations of cgi, perl...  [rate 1:28]
    
    cgi: 56 secs ( 0.33 usr 0.28 sys = 0.61 cpu) 
    perl: 2 secs ( 0.31 usr 0.27 sys = 0.58 cpu) 
    
    Benchmark: timing 1000 iterations of cgi,perl...  [rate 1:21]
     
    cgi: 567 secs ( 3.27 usr 2.83 sys = 6.10 cpu) 
    perl: 26 secs ( 3.11 usr 2.53 sys = 5.64 cpu)      
    
    Benchmark: timing 10000 iterations of cgi, perl   [rate 1:21]
     
    cgi: 6494 secs (34.87 usr 26.68 sys = 61.55 cpu) 
    perl: 299 secs (32.51 usr 23.98 sys = 56.49 cpu)

We don't know what server configurations were used for these tests, but I guess the numbers speak for themselves.

The source code of the script was available at http://www.realtime.net/~parkerm/perl/conf98/sld006.htm. It's now a dead link. If you know its new location, please let me know.



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Benchmarking Response Times

In the next sections we will talk about tools that allow us to benchmark response times.



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ApacheBench

ApacheBench (ab) is a tool for benchmarking your Apache HTTP server. It is designed to give you an idea of the performance that your current Apache installation can give. In particular, it shows you how many requests per second your Apache server is capable of serving. The ab tool comes bundled with the Apache source distribution.

Let's try it. We will simulate 10 users concurrently requesting a very light script at www.example.com/perl/test.pl. Each simulated user makes 10 requests.

  % ./ab -n 100 -c 10 www.example.com/perl/test.pl

The results are:

  Document Path:          /perl/test.pl
  Document Length:        319 bytes
  
  Concurrency Level:      10
  Time taken for tests:   0.715 seconds
  Complete requests:      100
  Failed requests:        0
  Total transferred:      60700 bytes
  HTML transferred:       31900 bytes
  Requests per second:    139.86
  Transfer rate:          84.90 kb/s received
  
  Connection Times (ms)
                min   avg   max
  Connect:        0     0     3
  Processing:    13    67    71
  Total:         13    67    74

We can see that under load of ten concurrent users our server is capable of processing 140 requests per second. Of course this benchmark is correct only when the script under test is used. We can also learn about the average processing time, which in this case was 67 milli-seconds. Other numbers reported by ab may or may not be of interest to you.

For example if we believe that the script perl/test.pl is not efficient we will try to improve it and run the benchmark again, to see whether we have any improve in performance.

HTTPD::Bench::ApacheBench, available from CPAN, provides a Perl interface for ab.



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httperf

httperf is a utility written by David Mosberger. Just like ApacheBench, it measures the performance of the webserver.

A sample command line is shown below:

  httperf --server hostname --port 80 --uri /test.html \
   --rate 150 --num-conn 27000 --num-call 1 --timeout 5

This command causes httperf to use the web server on the host with IP name hostname, running at port 80. The web page being retrieved is /test.html and, in this simple test, the same page is retrieved repeatedly. The rate at which requests are issued is 150 per second. The test involves initiating a total of 27,000 TCP connections and on each connection one HTTP call is performed. A call consists of sending a request and receiving a reply.

The timeout option defines the number of seconds that the client is willing to wait to hear back from the server. If this timeout expires, the tool considers the corresponding call to have failed. Note that with a total of 27,000 connections and a rate of 150 per second, the total test duration will be approximately 180 seconds (27,000/150), independently of what load the server can actually sustain. Here is a result that one might get:

     Total: connections 27000 requests 26701 replies 26701 test-duration 179.996 s
    
     Connection rate: 150.0 conn/s (6.7 ms/conn, <=47 concurrent connections)
     Connection time [ms]: min 1.1 avg 5.0 max 315.0 median 2.5 stddev 13.0
     Connection time [ms]: connect 0.3
     
     Request rate: 148.3 req/s (6.7 ms/req)
     Request size [B]: 72.0
     
     Reply rate [replies/s]: min 139.8 avg 148.3 max 150.3 stddev 2.7 (36 samples)
     Reply time [ms]: response 4.6 transfer 0.0
     Reply size [B]: header 222.0 content 1024.0 footer 0.0 (total 1246.0)
     Reply status: 1xx=0 2xx=26701 3xx=0 4xx=0 5xx=0
     
     CPU time [s]: user 55.31 system 124.41 (user 30.7% system 69.1% total 99.8%)
     Net I/O: 190.9 KB/s (1.6*10^6 bps)
     
     Errors: total 299 client-timo 299 socket-timo 0 connrefused 0 connreset 0
     Errors: fd-unavail 0 addrunavail 0 ftab-full 0 other 0

httperf download



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http_load

http_load is yet another utility that does webserver load testing. It can simulate 33.6kbps modem connection (-throttle) and allows you to provide a file with a list of URLs, which we be fetched randomly. You can specify how many parallel connections to run using the -parallel N option, or you can specify the number of requests to generate per second with -rate N option. Finally you can tell the utility when to stop by specifying either the test time length (-seconds N) or the total number of fetches (-fetches N).

A sample run with the file urls including:

  http://www.example.com/foo/
  http://www.example.com/bar/

We ask to generate three requests per second and run for only two seconds. Here is the generated output:

  % ./http_load -rate 3 -seconds 2 urls
  http://www.example.com/foo/: check-connect SUCCEEDED, ignoring
  http://www.example.com/bar/: check-connect SUCCEEDED, ignoring
  http://www.example.com/bar/: check-connect SUCCEEDED, ignoring
  http://www.example.com/bar/: check-connect SUCCEEDED, ignoring
  http://www.example.com/foo/: check-connect SUCCEEDED, ignoring
  5 fetches, 3 max parallel, 96870 bytes, in 2.00258 seconds
  19374 mean bytes/connection
  2.49678 fetches/sec, 48372.7 bytes/sec
  msecs/connect: 1.805 mean, 5.24 max, 0.79 min
  msecs/first-response: 291.289 mean, 560.338 max, 34.349 min

So you can see that it has reported 2.5 requests per second. Of course for the real test you will want to load the server heavily and run the test for a longer time to get more reliable results.

Note that when you provide a file with a list of URLs make sure that you don't have empty lines in it. If you do -- the utility won't work complaining:

  ./http_load: unknown protocol -

http_load download



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the crashme Script

This is another crashme suite originally written by Michael Schilli (and was located at http://www.linux-magazin.de site, but now the link has gone). I made a few modifications, mostly adding my () operators. I also allowed it to accept more than one url to test, since sometimes you want to test more than one script.

The tool provides the same results as ab above but it also allows you to set the timeout value, so requests will fail if not served within the time out period. You also get values for Latency (seconds per request) and Throughput (requests per second). It can do a complete simulation of your favorite Netscape browser :) and give you a better picture.

I have noticed while running these two benchmarking suites, that ab gave me results from two and a half to three times better. Both suites were run on the same machine, with the same load and the same parameters, but the implementations were different.

Sample output:

  URL(s):          http://www.example.com/perl/access/access.cgi
  Total Requests:  100
  Parallel Agents: 10
  Succeeded:       100 (100.00%)
  Errors:          NONE
  Total Time:      9.39 secs
  Throughput:      10.65 Requests/sec
  Latency:         0.85 secs/Request

And the code:

The LWP::Parallel::UserAgent benchmark: code/lwp-bench.pl



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Benchmarking PerlHandlers

The Apache::Timeit module does PerlHandler Benchmarking. With the help of this module you can log the time taken to process the request, just like you'd use the Benchmark module to benchmark a regular Perl script. Of course you can extend this module to perform more advanced processing like putting the results into a database for a later processing. But all it takes is adding this configuration directive inside httpd.conf:

  PerlFixupHandler Apache::Timeit

Since scripts running under Apache::Registry are running inside the PerlHandler these are benchmarked as well.

An example of the lines which show up in the error_log file:

  timing request for /perl/setupenvoff.pl:
    0 wallclock secs ( 0.04 usr +  0.01 sys =  0.05 CPU)
  timing request for /perl/setupenvoff.pl:
    0 wallclock secs ( 0.03 usr +  0.00 sys =  0.03 CPU)

The Apache::Timeit package is a part of the Apache-Perl-contrib files collection available from CPAN.



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Other Benchmarking Tools

Other tools you may want to take a look at:



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Code Profiling Techniques

The profiling process helps you to determine which subroutines or just snippets of code take the longest time to execute and which subroutines are called most often. Probably you will want to optimize those.

When do you need to profile your code? You do that when you suspect that some part of your code is called very often and may be there is a need to optimize it to significantly improve the overall performance.

For example if you have ever used the diagnostics pragma, which extends the terse diagnostics normally emitted by both the Perl compiler and the Perl interpreter, augmenting them with the more verbose and endearing descriptions found in the perldiag manpage. You know that it might tremendously slow you code down, so let's first prove that it is correct.

We will run a benchmark, once with diagnostics enabled and once disabled, on a subroutine called test_code.

The code inside the subroutine does an arithmetic and a numeric comparison of two strings. It assigns one string to another if the condition tests true but the condition always tests false. To demonstrate the diagnostics overhead the comparison operator is intentionally wrong. It should be a string comparison, not a numeric one.

  use Benchmark;
  use diagnostics;
  use strict;
  
  my $count = 50000;
  
  disable diagnostics;
  my $t1 = timeit($count,\&test_code);
  
  enable  diagnostics;
  my $t2 = timeit($count,\&test_code);
  
  print "Off: ",timestr($t1),"\n";
  print "On : ",timestr($t2),"\n";
  
  sub test_code{
    my ($a,$b) = qw(foo bar);
    my $c;
    if ($a == $b) {
      $c = $a;
    }
  }

For only a few lines of code we get:

  Off:  1 wallclock secs ( 0.81 usr +  0.00 sys =  0.81 CPU)
  On : 13 wallclock secs (12.54 usr +  0.01 sys = 12.55 CPU)

With diagnostics enabled, the subroutine test_code() is 16 times slower, than with diagnostics disabled!

Now let's fix the comparison the way it should be, by replacing == with eq, so we get:

    my ($a,$b) = qw(foo bar);
    my $c;
    if ($a eq $b) {
      $c = $a;
    }

and run the same benchmark again:

  Off:  1 wallclock secs ( 0.57 usr +  0.00 sys =  0.57 CPU)
  On :  1 wallclock secs ( 0.56 usr +  0.00 sys =  0.56 CPU)

Now there is no overhead at all. The diagnostics pragma slows things down only when warnings are generated.

After we have verified that using the diagnostics pragma might adds a big overhead to execution runtime, let's use the code profiling to understand why this happens. We are going to use Devel::DProf to profile the code. Let's use this code:

  diagnostics.pl
  --------------
  use diagnostics;
  print "Content-type:text/html\n\n";
  test_code();
  sub test_code{
    my ($a,$b) = qw(foo bar);
    my $c;
    if ($a == $b) {
      $c = $a;
    }
  }

Run it with the profiler enabled, and then create the profiling stastics with the help of dprofpp:

  % perl -d:DProf diagnostics.pl
  % dprofpp
  
  Total Elapsed Time = 0.342236 Seconds
    User+System Time = 0.335420 Seconds
  Exclusive Times
  %Time ExclSec CumulS #Calls sec/call Csec/c  Name
   92.1   0.309  0.358      1   0.3089 0.3578  main::BEGIN
   14.9   0.050  0.039   3161   0.0000 0.0000  diagnostics::unescape
   2.98   0.010  0.010      2   0.0050 0.0050  diagnostics::BEGIN
   0.00   0.000 -0.000      2   0.0000      -  Exporter::import
   0.00   0.000 -0.000      2   0.0000      -  Exporter::export
   0.00   0.000 -0.000      1   0.0000      -  Config::BEGIN
   0.00   0.000 -0.000      1   0.0000      -  Config::TIEHASH
   0.00   0.000 -0.000      2   0.0000      -  Config::FETCH
   0.00   0.000 -0.000      1   0.0000      -  diagnostics::import
   0.00   0.000 -0.000      1   0.0000      -  main::test_code
   0.00   0.000 -0.000      2   0.0000      -  diagnostics::warn_trap
   0.00   0.000 -0.000      2   0.0000      -  diagnostics::splainthis
   0.00   0.000 -0.000      2   0.0000      -  diagnostics::transmo
   0.00   0.000 -0.000      2   0.0000      -  diagnostics::shorten
   0.00   0.000 -0.000      2   0.0000      -  diagnostics::autodescribe

It's not easy to see what is responsible for this enormous overhead, even if main::BEGIN seems to be running most of the time. To get the full picture we must see the OPs tree, which shows us who calls whom, so we run:

  % dprofpp -T

and the output is:

 main::BEGIN
   diagnostics::BEGIN
      Exporter::import
         Exporter::export
   diagnostics::BEGIN
      Config::BEGIN
      Config::TIEHASH
      Exporter::import
         Exporter::export
   Config::FETCH
   Config::FETCH
   diagnostics::unescape
   .....................
   3159 times [diagnostics::unescape] snipped
   .....................
   diagnostics::unescape
   diagnostics::import
 diagnostics::warn_trap
   diagnostics::splainthis
      diagnostics::transmo
      diagnostics::shorten
      diagnostics::autodescribe
 main::test_code
   diagnostics::warn_trap
      diagnostics::splainthis
         diagnostics::transmo
         diagnostics::shorten
         diagnostics::autodescribe
   diagnostics::warn_trap
      diagnostics::splainthis
         diagnostics::transmo
         diagnostics::shorten
        diagnostics::autodescribe

So we see that two executions of diagnostics::BEGIN and 3161 of diagnostics::unescape are responsible for most of the running overhead.

If we comment out the diagnostics module, we get:

  Total Elapsed Time = 0.079974 Seconds
    User+System Time = 0.059974 Seconds
  Exclusive Times
  %Time ExclSec CumulS #Calls sec/call Csec/c  Name
   0.00   0.000 -0.000      1   0.0000      -  main::test_code

It is possible to profile code running under mod_perl with the Devel::DProf module, available on CPAN. However, you must have apache version 1.3b3 or higher and the PerlChildExitHandler enabled during the httpd build process. When the server is started, Devel::DProf installs an END block to write the tmon.out file. This block will be called at server shutdown. Here is how to start and stop a server with the profiler enabled:

  % setenv PERL5OPT -d:DProf
  % httpd -X -d `pwd` &
  ... make some requests to the server here ...
  % kill `cat logs/httpd.pid`
  % unsetenv PERL5OPT
  % dprofpp

The Devel::DProf package is a Perl code profiler. It will collect information on the execution time of a Perl script and of the subs in that script (remember that print() and map() are just like any other subroutines you write, but they come bundled with Perl!)

Another approach is to use Apache::DProf, which hooks Devel::DProf into mod_perl. The Apache::DProf module will run a Devel::DProf profiler inside each child server and write the tmon.out file in the directory $ServerRoot/logs/dprof/$$ when the child is shutdown (where $$ is the number of the child process). All it takes is to add to httpd.conf:

  PerlModule Apache::DProf

Remember that any PerlHandler that was pulled in before Apache::DProf in the httpd.conf or startup.pl, will not have its code debugging information inserted. To run dprofpp, chdir to $ServerRoot/logs/dprof/$$ and run:

  % dprofpp

(Lookup the ServerRoot directive's value in httpd.conf to figure out what's your $ServerRoot.)



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Measuring the Memory of the Process

Very important aspect of performance tuning is to make sure that your applications don't use much memory, since if they do you cannot run many servers and therefore in most cases under a heavy load the overall performance degrades.

In addition the code may not be clean and leak memory, which is even worse, since if the same process serves many requests and after each request more memory is used, after awhile all RAM will be used and machine will start swapping (use the swap partition) which is a very undesirable event, since it may lead to a machine crash.

The simplest way to figure out how big the processes are and see whether they grow is to watch the output of top(1) or ps(1) utilities.

For example the output of top(1):

    8:51am  up 66 days,  1:44,  1 user,  load average: 1.09, 2.27, 2.61
  95 processes: 92 sleeping, 3 running, 0 zombie, 0 stopped
  CPU states: 54.0% user,  9.4% system,  1.7% nice, 34.7% idle
  Mem:  387664K av, 309692K used,  77972K free, 111092K shrd,  70944K buff
  Swap: 128484K av,  11176K used, 117308K free                170824K cached

     PID USER PRI NI SIZE  RSS SHARE STAT LIB %CPU %MEM   TIME COMMAND
  29225 nobody 0  0  9760 9760  7132 S      0 12.5  2.5   0:00 httpd_perl
  29220 nobody 0  0  9540 9540  7136 S      0  9.0  2.4   0:00 httpd_perl
  29215 nobody 1  0  9672 9672  6884 S      0  4.6  2.4   0:01 httpd_perl
  29255 root   7  0  1036 1036   824 R      0  3.2  0.2   0:01 top
    376 squid  0  0 15920  14M   556 S      0  1.1  3.8 209:12 squid
  29227 mysql  5  5  1892 1892   956 S N    0  1.1  0.4   0:00 mysqld
  29223 mysql  5  5  1892 1892   956 S N    0  0.9  0.4   0:00 mysqld
  29234 mysql  5  5  1892 1892   956 S N    0  0.9  0.4   0:00 mysqld

Which starts with overall information of the system and then displays the most active processes at the given moment. So for example if we look at the httpd_perl processes we can see the size of the resident (RSS) and shared (SHARE) memory segments. This sample was taken on the production server running linux.

But of course we want to see all the apache/mod_perl processes, and that's where ps(1) comes to help. The options of this utility vary from one Unix flavor to another, and some flavors provide their own tools. Let's check the information about mod_perl processes:

  % ps -o pid,user,rss,vsize,%cpu,%mem,ucomm -C httpd_perl
    PID USER      RSS   VSZ %CPU %MEM COMMAND
  29213 root     8584 10264  0.0  2.2 httpd_perl
  29215 nobody   9740 11316  1.0  2.5 httpd_perl
  29216 nobody   9668 11252  0.7  2.4 httpd_perl
  29217 nobody   9824 11408  0.6  2.5 httpd_perl
  29218 nobody   9712 11292  0.6  2.5 httpd_perl
  29219 nobody   8860 10528  0.0  2.2 httpd_perl
  29220 nobody   9616 11200  0.5  2.4 httpd_perl
  29221 nobody   8860 10528  0.0  2.2 httpd_perl
  29222 nobody   8860 10528  0.0  2.2 httpd_perl
  29224 nobody   8860 10528  0.0  2.2 httpd_perl
  29225 nobody   9760 11340  0.7  2.5 httpd_perl
  29235 nobody   9524 11104  0.4  2.4 httpd_perl

Now you can see the resident (RSS) and virtual (VSZ) memory segments (and shared memory segment if you ask for it) of all mod_perl processes. Please refer to the top(1) and ps(1) man pages for more information.

You probably agree that using top(1) and ps(1) is cumbersome if we want to use memory size sampling during the benchmark test. We want to have a way to print memory sizes during the program execution at desired places. If you have GTop modules installed, which is a perl glue to the libgtop library, it's exactly what we need.

Note: GTop requires the libgtop library but is not available for all platforms. See the docs in the source at ftp://ftp.gnome.org/pub/GNOME/stable/sources/gtop/ to check whether your platform/flavor is supported.

GTop provides an API for retrieval of information about processes and the whole system. We are interested only in memory sampling API methods. To print all the process related memory information we can execute the following code:

  use GTop;
  my $gtop = GTop->new;
  my $proc_mem = $gtop->proc_mem($$);
  for (qw(size vsize share rss)) {
      printf "   %s => %d\n", $_, $proc_mem->$_();
  }

When executed we see the following output (in bytes):

      size => 1900544
     vsize => 3108864
     share => 1392640
       rss => 1900544

So if we are interested in to print the process resident memory segment before and after some event we just do it: For example if we want to see how much extra memory was allocated after a variable creation we can write the following code:

  use GTop;
  my $gtop = GTop->new;
  my $before = $gtop->proc_mem($$)->rss;
  my $x = 'a' x 10000;
  my $after  = $gtop->proc_mem($$)->rss;
  print "diff: ",$after-$before, " bytes\n";

and the output

  diff: 20480 bytes

So we can see that Perl has allocated extra 20480 bytes to create $x (of course the creation of after needed a few bytes as well, but it's insignificant compared to a size of $x)

The Apache::VMonitor module with help of the GTop module allows you to watch all your system information using your favorite browser from anywhere in the world without a need to telnet to your machine. If you are looking at what information you can retrieve with GTop, you should look at Apache::VMonitor as it deploys a big part of the API GTop provides.

If you are running a true BSD system, you may use BSD::Resource::getrusage instead of GTop. For example:

  print "used memory = ".(BSD::Resource::getrusage)[2]."\n"

For more information refer to the BSD::Resource manpage.



TOP

Measuring the Memory Usage of Subroutines

With help of Apache::Status you can find out the size of each and every subroutine.

  1. Build and install mod_perl as you always do, make sure it's version 1.22 or higher.

  2. Configure /perl-status if you haven't already:

      <Location /perl-status>
        SetHandler perl-script
        PerlHandler Apache::Status
        order deny,allow
        #deny from all
        #allow from ...
      </Location>
  3. Add to httpd.conf

      PerlSetVar StatusOptionsAll On
      PerlSetVar StatusTerse On
      PerlSetVar StatusTerseSize On
      PerlSetVar StatusTerseSizeMainSummary On
    
      PerlModule B::TerseSize
  4. Start the server (best in httpd -X mode)

  5. From your favorite browser fetch http://localhost/perl-status

  6. Click on 'Loaded Modules' or 'Compiled Registry Scripts'

  7. Click on the module or script of your choice (you might need to run some script/handler before you will see it here unless it was preloaded)

  8. Click on 'Memory Usage' at the bottom

  9. You should see all the subroutines and their respective sizes.

Now you can start to optimize your code. Or test which of the several implementations is of the least size.

For example let's compare CGI.pm's OO vs. procedural interfaces:

As you will see below the first OO script uses about 2k bytes while the second script (procedural interface) uses about 5k.

Here are the code examples and the numbers:

  1.   cgi_oo.pl
      ---------
      use CGI ();
      my $q = CGI->new;
      print $q->header;
      print $q->b("Hello");
  2.   cgi_mtd.pl
      ---------
      use CGI qw(header b);
      print header();
      print b("Hello");

After executing each script in single server mode (-X) the results are:

  1.   Totals: 1966 bytes | 27 OPs
    
      handler 1514 bytes | 27 OPs
      exit     116 bytes |  0 OPs
  2.   Totals: 4710 bytes | 19 OPs
      
      handler  1117 bytes | 19 OPs
      basefont  120 bytes |  0 OPs
      frameset  120 bytes |  0 OPs
      caption   119 bytes |  0 OPs
      applet    118 bytes |  0 OPs
      script    118 bytes |  0 OPs
      ilayer    118 bytes |  0 OPs
      header    118 bytes |  0 OPs
      strike    118 bytes |  0 OPs
      layer     117 bytes |  0 OPs
      table     117 bytes |  0 OPs
      frame     117 bytes |  0 OPs
      style     117 bytes |  0 OPs
      Param     117 bytes |  0 OPs
      small     117 bytes |  0 OPs
      embed     117 bytes |  0 OPs
      font      116 bytes |  0 OPs
      span      116 bytes |  0 OPs
      exit      116 bytes |  0 OPs
      big       115 bytes |  0 OPs
      div       115 bytes |  0 OPs
      sup       115 bytes |  0 OPs
      Sub       115 bytes |  0 OPs
      TR        114 bytes |  0 OPs
      td        114 bytes |  0 OPs
      Tr        114 bytes |  0 OPs
      th        114 bytes |  0 OPs
      b         113 bytes |  0 OPs

Note, that the above is correct if you didn't precompile all CGI.pm's methods at server startup. Since if you did, the procedural interface in the second test will take up to 18k and not 5k as we saw. That's because the whole of CGI.pm's namespace is inherited and it already has all its methods compiled, so it doesn't really matter whether you attempt to import only the symbols that you need. So if you have:

  use CGI  qw(-compile :all);

in the server startup script. Having:

  use CGI qw(header);

or

  use CGI qw(:all);

is essentially the same. You will have all the symbols precompiled at startup imported even if you ask for only one symbol. It seems to me like a bug, but probably that's how CGI.pm works.

BTW, you can check the number of opcodes in the code by a simple command line run. For example comparing 'my %hash' vs. 'my %hash = ()'.

  % perl -MO=Terse -e 'my %hash' | wc -l
  -e syntax OK
      4

  % perl -MO=Terse -e 'my %hash = ()' | wc -l
  -e syntax OK
     10

The first one has less opcodes.

Note that you shouldn't use Apache::Status module on production server as it adds quite a bit of overhead for each request.



TOP

Know Your Operating System

In order to get the best performance it helps to get intimately familiar with the Operating System (OS) the web server is running on. There are many OS specific things that you may be able to optimize which will improve your web server's speed, reliability and security.

The following sections will reveal some of the most important details you should know about your OS.



TOP

Sharing Memory

The sharing of memory is one very important factor. If your OS supports it (and most sane systems do), you might save memory by sharing it between child processes. This is only possible when you preload code at server startup. However, during a child process' life its memory pages tend to become unshared.

There is no way we can make Perl allocate memory so that (dynamic) variables land on different memory pages from constants, so the copy-on-write effect (we will explain this in a moment) will hit you almost at random.

If you are pre-loading many modules you might be able to trade off the memory that stays shared against the time for an occasional fork by tuning MaxRequestsPerChild. Each time a child reaches this upper limit and dies it should release its unshared pages. The new child which replaces it will share its fresh pages until it scribbles on them.

The ideal is a point where your processes usually restart before too much memory becomes unshared. You should take some measurements to see if it makes a real difference, and to find the range of reasonable values. If you have success with this tuning the value of MaxRequestsPerChild will probably be peculiar to your situation and may change with changing circumstances.

It is very important to understand that your goal is not to have MaxRequestsPerChild to be 10000. Having a child serving 300 requests on precompiled code is already a huge overall speedup, so if it is 100 or 10000 it probably does not really matter if you can save RAM by using a lower value.

Do not forget that if you preload most of your code at server startup, the newly forked child gets ready very fast, because it inherits most of the preloaded code and the perl interpreter from the parent process.

During the life of the child its memory pages (which aren't really its own to start with, it uses the parent's pages) gradually get `dirty' - variables which were originally inherited and shared are updated or modified -- and the copy-on-write happens. This reduces the number of shared memory pages, thus increasing the memory requirement. Killing the child and spawning a new one allows the new child to get back to the pristine shared memory of the parent process.

The recommendation is that MaxRequestsPerChild should not be too large, otherwise you lose some of the benefit of sharing memory.

See Choosing MaxRequestsPerChild for more about tuning the MaxRequestsPerChild parameter.



TOP

How Shared Is My Memory?

You've probably noticed that the word shared is repeated many times in relation to mod_perl. Indeed, shared memory might save you a lot of money, since with sharing in place you can run many more servers than without it. See the Formula and the numbers.

How much shared memory do you have? You can see it by either using the memory utility that comes with your system or you can deploy the GTop module:

  use GTop ();
  print "Shared memory of the current process: ",
    GTop->new->proc_mem($$)->share,"\n";
  
  print "Total shared memory: ",
    GTop->new->mem->share,"\n";

When you watch the output of the top utility, don't confuse the RES (or RSS) columns with the SHARE column. RES is RESident memory, which is the size of pages currently swapped in.



TOP

Calculating Real Memory Usage

I have shown how to measure the size of the process' shared memory, but we still want to know what the real memory usage is. Obviously this cannot be calculated simply by adding up the memory size of each process because that wouldn't account for the shared memory.

On the other hand we cannot just subtract the shared memory size from the total size to get the real memory usage numbers, because in reality each process has a different history of processed requests, therefore the shared memory is not the same for all processes.

So how do we measure the real memory size used by the server we run? It's probably too difficult to give the exact number, but I've found a way to get a fair approximation which was verified in the following way. I have calculated the real memory used, by the technique you will see in the moment, and then have stopped the Apache server and saw that the memory usage report indicated that the total used memory went down by almost the same number I've calculated. Note that some OSs do smart memory pages caching so you may not see the memory usage decrease as soon as it actually happens when you quit the application.

This is a technique I've used:

  1. For each process sum up the difference between shared and system memory. To calculate a difference for a single process use:

      use GTop;
      my $proc_mem = GTop->new->proc_mem($$);
      my $diff     = $proc_mem->size - $proc_mem->share;
      print "Difference is $diff bytes\n";
  2. Now if we add the shared memory size of the process with maximum shared memory, we will get all the memory that actually is being used by all httpd processes, except for the parent process.

  3. Finally, add the size of the parent process.

Please note that this might be incorrect for your system, so you use this number on your own risk.

I've used this technique to display real memory usage in the module Apache::VMonitor, so instead of trying to manually calculate this number you can use this module to do it automatically. In fact in the calculations used in this module there is no separation between the parent and child processes, they are all counted indifferently using the following code:

  use GTop ();
  my $gtop = GTop->new;
  my $total_real = 0;
  my $max_shared = 0;
  # @mod_perl_pids is initialized by Apache::Scoreboard, irrelevant here
  my @mod_perl_pids = some_code();
  for my $pid (@mod_perl_pids)
    my $proc_mem = $gtop->proc_mem($pid);
    my $size     = $proc_mem->size($pid);
    my $share    = $proc_mem->share($pid);
    $total_real += $size - $share;
    $max_shared  = $share if $max_shared < $share;
  }
  my $total_real += $max_shared;

So as you see we that we accumulate the difference between the shared and reported memory:

    $total_real  += $size-$share;

and at the end add the biggest shared process size:

  my $total_real += $max_shared;

So now $total_real contains approximately the really used memory.



TOP

Are My Variables Shared?

How do you find out if the code you write is shared between the processes or not? The code should be shared, except where it is on a memory page with variables that change. Some variables are read-only in usage and never change. For example, if you have some variables that use a lot of memory and you want them to be read-only. As you know the variable becomes unshared when the process modifies its value.

So imagine that you have this 10Mb in-memory database that resides in a single variable, you perform various operations on it and want to make sure that the variable is still shared. For example if you do some matching regular expression (regex) processing on this variable and want to use the pos() function, will it make the variable unshared or not?

The Apache::Peek module comes to rescue. Let's write a module called MyShared.pm which we preload at server startup, so all the variables of this module are initially shared by all children.

  MyShared.pm
  ---------
  package MyShared;
  use Apache::Peek;
  
  my $readonly = "Chris";
  
  sub match    { $readonly =~ /\w/g;               }
  sub print_pos{ print "pos: ",pos($readonly),"\n";}
  sub dump     { Dump($readonly);                  }
  1;

This module declares the package MyShared, loads the Apache::Peek module and defines the lexically scoped $readonly variable which is supposed to be a variable of large size (think about a huge hash data structure), but we will use a small one to simplify this example.

The module also defines three subroutines: match() that does a simple character matching, print_pos() that prints the current position of the matching engine inside the string that was last matched and finally the dump() subroutine that calls the Apache::Peek module's Dump() function to dump a raw Perl data-type of the $readonly variable.

Now we write the script that prints the process ID (PID) and calls all three functions. The goal is to check whether pos() makes the variable dirty and therefore unshared.

  share_test.pl
  -------------
  use MyShared;
  print "Content-type: text/plain\r\n\r\n";
  print "PID: $$\n";
  MyShared::match();
  MyShared::print_pos();
  MyShared::dump();

Before you restart the server, in httpd.conf set:

  MaxClients 2

for easier tracking. You need at least two servers to compare the print outs of the test program. Having more than two can make the comparison process harder.

Now open two browser windows and issue the request for this script several times in both windows, so you get different processes PIDs reported in the two windows and each process has processed a different number of requests to the share_test.pl script.

In the first window you will see something like that:

  PID: 27040
  pos: 1
  SV = PVMG(0x853db20) at 0x8250e8c
    REFCNT = 3
    FLAGS = (PADBUSY,PADMY,SMG,POK,pPOK)
    IV = 0
    NV = 0
    PV = 0x8271af0 "Chris"\0
    CUR = 5
    LEN = 6
    MAGIC = 0x853dd80
      MG_VIRTUAL = &vtbl_mglob
      MG_TYPE = 'g'
      MG_LEN = 1

And in the second window:

  PID: 27041
  pos: 2
  SV = PVMG(0x853db20) at 0x8250e8c
    REFCNT = 3
    FLAGS = (PADBUSY,PADMY,SMG,POK,pPOK)
    IV = 0
    NV = 0
    PV = 0x8271af0 "Chris"\0
    CUR = 5
    LEN = 6
    MAGIC = 0x853dd80
      MG_VIRTUAL = &vtbl_mglob
      MG_TYPE = 'g'
      MG_LEN = 2

We see that all the addresses of the supposedly big structures are the same, 0x8250e8c for SV, and 0x8271af0 for PV, therefore the variable data structure is almost completely shared. The only difference is in SV.MAGIC.MG_LEN record, which is not shared.

So given that the $readonly variable is a big one, its value is still shared between the processes, while part of the variable data structure is non-shared. But it's almost insignificant because it takes a very little memory space.

Now if you need to compare more than variable, doing it by hand can be quite time consuming and error prune. Therefore it's better to correct the testing script to dump the Perl data-types into files (e.g /tmp/dump.$$, where $$ is the PID of the process) and then using diff(1) utility to see whether there is some difference.

So correcting the dump() function to write the info to the file will do the job. Notice that we use Devel::Peek and not Apache::Peek. The both are almost the same, but Apache::Peek prints it output directly to the opened socket so we cannot intercept and redirect the result to the file. Since Devel::Peek dumps results to the STDERR stream we can use the old trick of saving away the default STDERR handler, and open a new filehandler using the STDERR. In our example when Devel::Peek now prints to STDERR it actually prints to our file. When we are done, we make sure to restore the original STDERR filehandler.

So this is the resulting code:

  MyShared2.pm
  ---------
  package MyShared2;
  use Devel::Peek;
  
  my $readonly = "Chris";
  
  sub match    { $readonly =~ /\w/g;               }
  sub print_pos{ print "pos: ",pos($readonly),"\n";}
  sub dump{
    my $dump_file = "/tmp/dump.$$";
    print "Dumping the data into $dump_file\n";
    open OLDERR, ">&STDERR";
    open STDERR, ">".$dump_file or die "Can't open $dump_file: $!";
    Dump($readonly);
    close STDERR ;
    open STDERR, ">&OLDERR";
  }
  1;

When if we modify the code to use the modified module:

  share_test2.pl
  -------------
  use MyShared2;
  print "Content-type: text/plain\r\n\r\n";
  print "PID: $$\n";
  MyShared2::match();
  MyShared2::print_pos();
  MyShared2::dump();

And run it as before (with MaxClients 2), two dump files will be created in the directory /tmp. In our test these were created as /tmp/dump.1224 and /tmp/dump.1225. When we run diff(1):

  % diff /tmp/dump.1224 /tmp/dump.1225
  12c12
  <       MG_LEN = 1
  ---
  >       MG_LEN = 2

We see that the two padlists (of the variable readonly) are different, as we have observed before when we did a manual comparison.

In fact we if we think about these results again, we get to a conclusion that there is no need for two processes to find out whether the variable gets modified (and therefore unshared). It's enough to check the datastructure before the script was executed and after that. You can modify the MyShared2 module to dump the padlists into a different file after each invocation and than to run the diff(1) on the two files.

If you want to watch whether some lexically scoped (with my ()) variables in your Apache::Registry script inside the same process get changed between invocations you can use the Apache::RegistryLexInfo module instead. Since it does exactly this: it makes a snapshot of the padlist before and after the code execution and shows the difference between the two. This specific module was written to work with Apache::Registry scripts so it won't work for loaded modules. Use the technique we have described above for any type of variables in modules and scripts.

Surely another way of ensuring that a scalar is readonly and therefore sharable is to either use the constant pragma or readonly pragma. But then you won't be able to make calls that alter the variable even a little, like in the example that we just showed, because it will be a true constant variable and you will get compile time error if you try this:

  MyConstant.pm
  -------------
  package MyConstant;
  use constant readonly => "Chris";
  
  sub match    { readonly =~ /\w/g;               }
  sub print_pos{ print "pos: ",pos(readonly),"\n";}
  1;

  % perl -c MyConstant.pm

  Can't modify constant item in match position at MyConstant.pm line
  5, near "readonly)"
  MyConstant.pm had compilation errors.

However this code is just right:

  MyConstant1.pm
  -------------
  package MyConstant1;
  use constant readonly => "Chris";
  
  sub match { readonly =~ /\w/g; }
  1;


TOP

Preloading Perl Modules at Server Startup

You can use the PerlRequire and PerlModule directives to load commonly used modules such as CGI.pm, DBI and etc., when the server is started. On most systems, server children will be able to share the code space used by these modules. Just add the following directives into httpd.conf:

  PerlModule CGI
  PerlModule DBI

But an even better approach is to create a separate startup file (where you code in plain perl) and put there things like:

  use DBI ();
  use Carp ();

Don't forget to prevent importing of the symbols exported by default by the module you are going to preload, by placing empty parentheses () after a module's name. Unless you need some of these in the startup file, which is unlikely. This will save you a few more memory bits.

Then you require() this startup file in httpd.conf with the PerlRequire directive, placing it before the rest of the mod_perl configuration directives:

  PerlRequire /path/to/start-up.pl

CGI.pm is a special case. Ordinarily CGI.pm autoloads most of its functions on an as-needed basis. This speeds up the loading time by deferring the compilation phase. When you use mod_perl, FastCGI or another system that uses a persistent Perl interpreter, you will want to precompile the functions at initialization time. To accomplish this, call the package function compile() like this:

  use CGI ();
  CGI->compile(':all');

The arguments to compile() are a list of method names or sets, and are identical to those accepted by the use() and import() operators. Note that in most cases you will want to replace ':all' with the tag names that you actually use in your code, since generally you only use a subset of them.

Let's conduct a memory usage test to prove that preloading, reduces memory requirements.

In order to have an easy measurement we will use only one child process, therefore we will use this setting:

  MinSpareServers 1
  MaxSpareServers 1
  StartServers 1
  MaxClients 1
  MaxRequestsPerChild 100

We are going to use the Apache::Registry script memuse.pl which consists of two parts: the first one preloads a bunch of modules (that most of them aren't going to be used), the second part reports the memory size and the shared memory size used by the single child process that we start. and of course it prints the difference between the two sizes.

  memuse.pl
  ---------
  use strict;
  use CGI ();
  use DB_File ();
  use LWP::UserAgent ();
  use Storable ();
  use DBI ();
  use GTop ();

  my $r = shift;
  $r->send_http_header('text/plain');
  my $proc_mem = GTop->new->proc_mem($$);
  my $size  = $proc_mem->size;
  my $share = $proc_mem->share;
  my $diff  = $size - $share;
  printf "%10s %10s %10s\n", qw(Size Shared Difference);
  printf "%10d %10d %10d (bytes)\n",$size,$share,$diff;

First we restart the server and execute this CGI script when none of the above modules preloaded. Here is the result:

     Size   Shared     Diff
  4706304  2134016  2572288 (bytes)

Now we take all the modules:

  use strict;
  use CGI ();
  use DB_File ();
  use LWP::UserAgent ();
  use Storable ();
  use DBI ();
  use GTop ();

and copy them into the startup script, so they will get preloaded. The script remains unchanged. We restart the server and execute it again. We get the following.

     Size   Shared    Diff
  4710400  3997696  712704 (bytes)

Let's put the two results into one table:

  Preloading    Size   Shared     Diff
     Yes     4710400  3997696   712704 (bytes)
      No     4706304  2134016  2572288 (bytes)
  --------------------------------------------
  Difference    4096  1863680 -1859584

You can clearly see that when the modules weren't preloaded the shared memory pages size, were about 1864Kb smaller relative to the case where the modules were preloaded.

Assuming that you have had 256M dedicated to the web server, if you didn't preload the modules, you could have:

  268435456 = X * 2572288 + 2134016

  X = (268435456 - 2134016) / 2572288 = 103

103 servers.

Now let's calculate the same thing with modules preloaded:

  268435456 = X * 712704 + 3997696

  X = (268435456 - 3997696) / 712704 = 371

You can have almost 4 times more servers!!!

Remember that we have mentioned before that memory pages gets dirty and the size of the shared memory gets smaller with time? So we have presented the ideal case where the shared memory stays intact. Therefore the real numbers will be a little bit different, but not far from the numbers in our example.

Also it's obvious that in your case it's possible that the process size will be bigger and the shared memory will be smaller, since you will use different modules and a different code, so you won't get this fantastic ratio, but this example is certainly helps to feel the difference.



TOP

Preloading Registry Scripts at Server Startup

What happens if you find yourself stuck with Perl CGI scripts and you cannot or don't want to move most of the stuff into modules to benefit from modules preloading, so the code will be shared by the children. Luckily you can preload scripts as well. This time the Apache::RegistryLoader modules comes to aid. Apache::RegistryLoader compiles Apache::Registry scripts at server startup.

For example to preload the script /perl/test.pl which is in fact the file /home/httpd/perl/test.pl you would do the following:

  use Apache::RegistryLoader ();
  Apache::RegistryLoader->new->handler("/perl/test.pl",
                    "/home/httpd/perl/test.pl");

You should put this code either into <Perl> sections or into a startup script.

But what if you have a bunch of scripts located under the same directory and you don't want to list them one by one. Take the benefit of Perl modules and put them to a good use. The File::Find module will do most of the work for you.

The following code walks the directory tree under which all Apache::Registry scripts are located. For each encountered file with extension .pl, it calls the Apache::RegistryLoader::handler() method to preload the script in the parent server, before pre-forking the child processes:

  use File::Find qw(finddepth);
  use Apache::RegistryLoader ();
  {
    my $scripts_root_dir = "/home/httpd/perl/";
    my $rl = Apache::RegistryLoader->new;
    finddepth
      (
       sub {
         return unless /\.pl$/;
         my $url = "$File::Find::dir/$_";
         $url =~ s|$scripts_root_dir/?|/|;
         warn "pre-loading $url\n";
           # preload $url
         my $status = $rl->handler($url);
         unless($status == 200) {
       warn "pre-load of `$url' failed, status=$status\n";
         }
       },
       $scripts_root_dir);
  }

Note that we didn't use the second argument to handler() here, as in the first example. To make the loader smarter about the URI to filename translation, you might need to provide a trans() function to translate the URI to filename. URI to filename translation normally doesn't happen until HTTP request time, so the module is forced to roll its own translation. If filename is omitted and a trans() function was not defined, the loader will try using the URI relative to ServerRoot.

A simple trans() function can be something like that:

  sub mytrans {
    my $uri = shift;
    $uri =~ s|^/perl/|/home/httpd/perl/|;
    return $uri;
  }

You can easily derive the right translation by looking at the Alias directive. The above mytrans() function is matching our Alias:

  Alias /perl/ /home/httpd/perl/

After defining the URI to filename translation function you should pass it during the creation of the Apache::RegistryLoader object:

  my $rl = Apache::RegistryLoader->new(trans => \&mytrans);

I won't show any benchmarks here, since the effect is absolutely the same as with preloading modules.

See also BEGIN blocks



TOP

Modules Initializing at Server Startup

We have just learned that it's important to preload the modules and scripts at the server startup. It turns out that it's not enough for some modules and you have to prerun their initialization code to get more memory pages shared. Basically you will find an information about specific modules in their respective manpages. We will present a few examples of widely used modules where the code can be initialized.



TOP

Initializing DBI.pm

The first example is the DBI module. As you know DBI works with many database drivers falling into the DBD:: category, e.g. DBD::mysql. It's not enough to preload DBI, you should initialize DBI with driver(s) that you are going to use (usually a single driver is used), if you want to minimize memory use after forking the child processes. Note that you want to do this under mod_perl and other environments where the shared memory is very important. Otherwise you shouldn't initialize drivers.

You probably know already that under mod_perl you should use the Apache::DBI module to get the connection persistence, unless you open a separate connection for each user--in this case you should not use this module. Apache::DBI automatically loads DBI and overrides some of its methods, so you should continue coding like there is only a DBI module.

Just as with modules preloading our goal is to find the startup environment that will lead to the smallest "difference" between the shared and normal memory reported, therefore a smaller total memory usage.

And again in order to have an easy measurement we will use only one child process, therefore we will use this setting in httpd.conf:

  MinSpareServers 1
  MaxSpareServers 1
  StartServers 1
  MaxClients 1
  MaxRequestsPerChild 100

We always preload these modules:

  use Gtop();
  use Apache::DBI(); # preloads DBI as well

We are going to run memory benchmarks on five different versions of the startup.pl file.

Here is the Apache::Registry test script that we have used:

  preload_dbi.pl
  --------------
  use strict;
  use GTop ();
  use DBI ();
    
  my $dbh = DBI->connect("DBI:mysql:test::localhost",
                         "",
                         "",
                         {
                          PrintError => 1, # warn() on errors
                          RaiseError => 0, # don't die on error
                          AutoCommit => 1, # commit executes
                                           # immediately
                         }
                        )
    or die "Cannot connect to database: $DBI::errstr";
  
  my $r = shift;
  $r->send_http_header('text/plain');
  
  my $do_sql = "show tables";
  my $sth = $dbh->prepare($do_sql);
  $sth->execute();
  my @data = ();
  while (my @row = $sth->fetchrow_array){
    push @data, @row;
  }
  print "Data: @data\n";
  $dbh->disconnect(); # NOP under Apache::DBI
  
  my $proc_mem = GTop->new->proc_mem($$);
  my $size  = $proc_mem->size;
  my $share = $proc_mem->share;
  my $diff  = $size - $share;
  printf "%8s %8s %8s\n", qw(Size Shared Diff);
  printf "%8d %8d %8d (bytes)\n",$size,$share,$diff;

The script opens a opens a connection to the database 'test' and issues a query to learn what tables the databases has. When the data is collected and printed the connection would be closed in the regular case, but Apache::DBI overrides it with empty method. When the data is processed a familiar to you already code to print the memory usage follows.

The server was restarted before each new test.

So here are the results of the five tests that were conducted, sorted by the Diff column:

  1. After the first request:

      Test type                              Size   Shared     Diff
      --------------------------------------------------------------
      install_driver (2)                   3465216  2621440   843776
      install_driver & connect_on_init (5) 3461120  2609152   851968
      preload driver (3)                   3465216  2605056   860160
      nothing added (1)                    3461120  2494464   966656
      connect_on_init (4)                  3461120  2482176   978944
  2. After the second request (all the subsequent request showed the same results):

      Test type                              Size   Shared     Diff
      --------------------------------------------------------------
      install_driver (2)                   3469312  2609152   860160
      install_driver & connect_on_init (5) 3481600  2605056   876544
      preload driver (3)                   3469312  2588672   880640
      nothing added  (1)                   3477504  2482176   995328
      connect_on_init (4)                  3481600  2469888  1011712

Now what do we conclude from looking at these numbers. First we see that only after a second reload we get the final memory footprint for a specific request in question (if you pass different arguments the memory usage might and will be different).

But both tables show the same pattern of memory usage. We can clearly see that the real winner is the startup.pl file's version where the MySQL driver was installed (2). Since we want to have a connection ready for the first request made to the freshly spawned child process, we generally use the version (5) which uses somewhat more memory, but has almost the same number of shared memory pages. The version (3) only preloads the driver which results in smaller shared memory. The last two versions having nothing initialized (1) and having only the connect_on_init() method used (4). The former is a little bit better than the latter, but both significantly worse than the first two versions.

To remind you why do we look for the smallest value in the column diff, recall the real memory usage formula:

  RAM_dedicated_to_mod_perl = diff * number_of_processes
                            + the_processes_with_largest_shared_memory

Notice that the smaller the diff is, the bigger the number of processes you can have using the same amount of RAM. Therefore every 100K difference counts, when you multiply it by the number of processes. If we take the number from the version (2) vs. (4) and assume that we have 256M of memory dedicated to mod_perl processes we will get the following numbers using the formula derived from the above formula:

               RAM - largest_shared_size
  N_of Procs = -------------------------
                        Diff

                268435456 - 2609152
  (ver 2)  N =  ------------------- = 309
                      860160

                268435456 - 2469888
  (ver 4)  N =  ------------------- = 262
                     1011712

So you can tell the difference (17% more child processes in the first version).



TOP

Initializing CGI.pm

CGI.pm is a big module that by default postpones the compilation of its methods until they are actually needed, thus making it possible to use it under a slow mod_cgi handler without adding a big overhead. That's not what we want under mod_perl and if you use CGI.pm you should precompile the methods that you are going to use at the server startup in addition to preloading the module. Use the compile method for that:

  use CGI;
  CGI->compile(':all');

where you should replace the tag group :all with the real tags and group tags that you are going to use if you want to optimize the memory usage.

We are going to compare the shared memory foot print by using the script which is back compatible with mod_cgi. You will see that you can improve performance of this kind of scripts as well, but if you really want a fast code think about porting it to use Apache::Request for CGI interface and some other module for HTML generation.

So here is the Apache::Registry script that we are going to use to make the comparison:

  preload_cgi_pm.pl
  -----------------
  use strict;
  use CGI ();
  use GTop ();

  my $q = new CGI;
  print $q->header('text/plain');
  print join "\n", map {"$_ => ".$q->param($_) } $q->param;
  print "\n";
  
  my $proc_mem = GTop->new->proc_mem($$);
  my $size  = $proc_mem->size;
  my $share = $proc_mem->share;
  my $diff  = $size - $share;
  printf "%8s %8s %8s\n", qw(Size Shared Diff);
  printf "%8d %8d %8d (bytes)\n",$size,$share,$diff;

The script initializes the CGI object, sends HTTP header and then print all the arguments and values that were passed to the script if at all. At the end as usual we print the memory usage.

As usual we are going to use a single child process, therefore we will use this setting in httpd.conf:

  MinSpareServers 1
  MaxSpareServers 1
  StartServers 1
  MaxClients 1
  MaxRequestsPerChild 100

We are going to run memory benchmarks on three different versions of the startup.pl file. We always preload this module:

  use Gtop();

The server was restarted before each new test.

So here are the results of the five tests that were conducted, sorted by the Diff column:

  1. After the first request:

      Version     Size   Shared     Diff        Test type
      --------------------------------------------------------------------
            1  3321856  2146304  1175552  not preloaded
            2  3321856  2326528   995328  preloaded
            3  3244032  2465792   778240  preloaded & methods+compiled
  2. After the second request (all the subsequent request showed the same results):

      Version     Size   Shared    Diff         Test type
      --------------------------------------------------------------------
            1  3325952  2134016  1191936 not preloaded
            2  3325952  2314240  1011712 preloaded
            3  3248128  2445312   802816 preloaded & methods+compiled

The first version shows the results of the script execution when CGI.pm wasn't preloaded. The second version with module preloaded. The third when it's both preloaded and the methods that are going to be used are precompiled at the server startup.

By looking at the version one of the second table we can conclude that, preloading adds about 20K of shared size. As we have mention at the beginning of this section that's how CGI.pm was implemented--to reduce the load overhead. Which means that preloading CGI is almost hardly change a thing. But if we compare the second and the third versions we will see a very significant difference of 207K (1011712-802816), and we have used only a few methods (the header method loads a few more method transparently for a user). Imagine how much memory we are going to save if we are going to precompile all the methods that we are using in other scripts that use CGI.pm and do a little bit more than the script that we have used in the test.

But even in our very simple case using the same formula, what do we see? (assuming that we have 256MB dedicated for mod_perl)

               RAM - largest_shared_size
  N_of Procs = -------------------------
                        Diff

                268435456 - 2134016
  (ver 1)  N =  ------------------- = 223
                      1191936

                268435456 - 2445312
  (ver 3)  N =  ------------------- = 331
                     802816

If we preload CGI.pm and precompile a few methods that we use in the test script, we can have 50% more child processes than when we don't preload and precompile the methods that we are going to use.

META: I've heard that the 3.x generation will be less bloated, so probably I'll have to rerun this using the new version.



TOP

Increasing Shared Memory With mergemem

mergemem is an experimental utility for linux, which looks very interesting for us mod_perl users: http://www.complang.tuwien.ac.at/ulrich/mergemem/

It looks like it could be run periodically on your server to find and merge duplicate pages. It won't halt your httpds during the merge, this aspect has been taken into consideration already during the design of mergemem: Merging is not performed with one big systemcall. Instead most operation is in userspace, making a lot of small systemcalls.

Therefore blocking of the system should not happen. And, if it really should turn out to take too much time you can reduce the priority of the process.

The worst case that can happen is this: mergemem merges two pages and immediately afterwards they will be split. The split costs about the same as the time consumed by merging.

This software comes with a utility called memcmp to tell you how much you might save.



TOP

Forking and Executing Subprocesses from mod_perl

It's desirable to avoid forking under mod_perl. Since when you do, you are forking the entire Apache server, lock, stock and barrel. Not only is your Perl code and Perl interpreter being duplicated, but so is mod_ssl, mod_rewrite, mod_log, mod_proxy, mod_speling (it's not a typo!) or whatever modules you have used in your server, all the core routines, etc.

Modern Operating Systems come with a very light version of fork which adds a little overhead when called, since it was optimized to do the absolute minimum of memory pages duplications. The copy-on-write technique is the one that allows to do so. The gist of this technique is as follows: the parent process memory pages aren't immediately copied to the child's space on fork(), but this is done only when the child or the parent modifies the data in some memory pages. Before the pages get modified they get marked as dirty and the child has no choice but to copy the pages that are to be modified since they cannot be shared any more.

If you need to call a Perl program from your mod_perl code, it's better to try to covert the program into a module and call it a function without spawning a special process to do that. Of course if you cannot do that or the program is not written in Perl, you have to call via system() or is equivalent, which spawn a new process. If the program written in C, you may try to write a Perl glue code with help of XS or SWIG architectures, and then the program will be executed as a perl subroutine.

Also by trying to spawn a sub-process, you might be trying to do the "wrong thing". If what you really want is to send information to the browser and then do some post-processing, look into the PerlCleanupHandler directive. The latter allows you to tell the child process after request has been processed and user has received the response. This doesn't release the mod_perl process to serve other requests, but it allows to send the response to the client faster. If this is the situation and you need to run some cleanup code, you may want to register this code during the request processing via:

  my $r = shift;
  $r->register_cleanup(\&do_cleanup);
  sub do_cleanup{ #some clean-up code here }

But when a long term process needs to be spawned, there is not much choice, but to use fork(). We cannot just run this long term process within Apache process, since it'll first keep the Apache process busy, instead of letting it do the job it was designed for. And second, if Apache will be stopped the long term process might be terminated as well, unless coded properly to detach from Apache processes group.

In the following sections we are going to discuss how to properly spawn new processes under mod_perl.



TOP

Forking a New Process

This is a typical way to call fork() under mod_perl:

  defined (my $kid = fork) or die "Cannot fork: $!\n";
  if ($kid) {
    # Parent runs this block
  } else {
    # Child runs this block
    # some code comes here
    CORE::exit(0);
  }
  # possibly more code here usually run by the parent

When using fork(), you should check its return value, since if it returns undef it means that the call was unsuccessful and no process was spawned. Something that can happen when the system is running too many processes and cannot spawn new ones.

When the process is successfully forked--the parent receives the PID of the newly spawned child as a returned value of the fork() call and the child receives 0. Now the program splits into two. In the above example the code inside the first block after if will be executed by the parent and the code inside the first block after else will be executed by the child process.

It's important not to forget to explicitly call exit() at the end of the child code when forking. Since if you don't and there is some code outside the if/else block, the child process will execute it as well. But under mod_perl there is another nuance--you must use CORE::exit() and not exit(), which would be automatically overridden by Apache::exit() if used in conjunction with Apache::Registry and similar modules. And we want the spawned process to quit when its work is done, otherwise it'll just stay alive use resources and do nothing.

The parent process usually completes its execution path and enters the pool of free servers to wait for a new assignment. If the execution path is to be aborted earlier for some reason one should use Apache::exit() or die(), in the case of Apache::Registry or Apache::PerlRun handlers a simple exit() will do the right thing.

The child shares with parent its memory pages until it has to modify some of them, which triggers a copy-on-write process which copies these pages to the child's domain before the child is allowed to modify them. But this all happens afterwards. At the moment the fork() call executed, the only work to be done before the child process goes on its separate way is setting up the page tables for the virtual memory, which imposes almost no delay at all.



TOP

Freeing the Parent Process

In the child code you must also close all the pipes to the connection socket that were opened by the parent process (i.e. STDIN and STDOUT) and inherited by the child, so the parent will be able to complete the request and free itself for serving other requests. If you need the STDIN and/or STDOUT streams you should re-open them. You may need to close or re-open the STDERR filehandle. It's opened to append to the error_log file as inherited from its parent, so chances are that you will want to leave it untouched.

Under mod_perl, the spawned process also inherits the file descriptor that's tied to the socket through which all the communications between the server and the client happen. Therefore we need to free this stream in the forked process. If we don't do that, the server cannot be restarted while the spawned process is still running. If an attempt is made to restart the server you will get the following error:

  [Mon Dec 11 19:04:13 2000] [crit] 
  (98)Address already in use: make_sock:
    could not bind to address 127.0.0.1 port 8000

Apache::SubProcess comes to help and provides a method cleanup_for_exec() which takes care of closing this file descriptor.

So the simplest way is to freeing the parent process is to close all three STD* streams if we don't need them and untie the Apache socket. In addition you may want to change process' current directory to / so the forked process won't keep the mounted partition busy, if this is to be unmounted at a later time. To summarize all this issues, here is an example of the fork that takes care of freeing the parent process.

  use Apache::SubProcess;
  defined (my $kid = fork) or die "Cannot fork: $!\n";
  if ($kid) {
    # Parent runs this block
  } else {
    # Child runs this block
      $r->cleanup_for_exec(); # untie the socket
      chdir '/' or die "Can't chdir to /: $!";
      close STDIN;
      close STDOUT;
      close STDERR;
  
    # some code comes here
  
      CORE::exit(0);
  }
  # possibly more code here usually run by the parent

Of course between the freeing the parent code and child process termination the real code is to be placed.



TOP

Detaching the Forked Process

Now what happens if the forked process is running and we decided that we need to restart the web-server? This forked process will be aborted, since when parent process will die during the restart it'll kill its child processes as well. In order to avoid this we need to detach the process from its parent session, by opening a new session with help of setsid() system call, provided by the POSIX module:

  use POSIX 'setsid';
  
  defined (my $kid = fork) or die "Cannot fork: $!\n";
  if ($kid) {
    # Parent runs this block
  } else {
    # Child runs this block
      setsid or die "Can't start a new session: $!";
      ...
  }

Now the spawned child process has a life of its own, and it doesn't depend on the parent anymore.



TOP

Avoiding Zombie Processes

Now let's talk about zombie processes.

Normally, every process has its parent. Many processes are children of the init process, whose PID is 1. When you fork a process you must wait() or waitpid() for it to finish. If you don't wait() for it, it becomes a zombie.

A zombie is a process that doesn't have a parent. When the child quits, it reports the termination to its parent. If no parent wait()s to collect the exit status of the child, it gets "confused" and becomes a ghost process, that can be seen as a process, but not killed. It will be killed only when you stop the parent process that spawned it!

Generally the ps(1) utility displays these processes with the <defunc> tag, and you will see the zombies counter increment when doing top(). These zombie processes can take up system resources and are generally undesirable.

So the proper way to do a fork is:

  my $r = shift;
  $r->send_http_header('text/plain');
  
  defined (my $kid = fork) or die "Cannot fork: $!";
  if ($kid) {
    waitpid($kid,0);
    print "Parent has finished\n";
  } else {
      # do something
      CORE::exit(0);
  }

In most cases the only reason you would want to fork is when you need to spawn a process that will take a long time to complete. So if the Apache process that spawns this new child process has to wait for it to finish, you have gained nothing. You can neither wait for its completion (because you don't have the time to), nor continue because you will get yet another zombie process. This is called a blocking call, since the process is blocked to do anything else before this call gets completed.

The simplest solution is to ignore your dead children. Just add this line before the fork() call:

  $SIG{CHLD} = 'IGNORE';

When you set the CHLD (SIGCHLD in C) signal handler to 'IGNORE', all the processes will be collected by the init process and are therefore prevented from becoming zombies. This doesn't work everywhere, however. It proved to work at least on Linux OS.

Note that you cannot localize this setting with local(). If you do, it won't have the desired effect.

[META: Can anyone explain why localization doesn't work?]

So now the code would look like this:

  my $r = shift;
  $r->send_http_header('text/plain');
  
  $SIG{CHLD} = 'IGNORE';
  
  defined (my $kid = fork) or die "Cannot fork: $!\n";
  if ($kid) {
      print "Parent has finished\n";
  } else {
      # do something time-consuming
      CORE::exit(0);
  }

Note that waitpid() call has gone. The $SIG{CHLD} = 'IGNORE'; statement protects us from zombies, as explained above.

Another, more portable, but slightly more expensive solution is to use a double fork approach.

  my $r = shift;
  $r->send_http_header('text/plain');
  
  defined (my $kid = fork) or die "Cannot fork: $!\n";
  if ($kid) {
    waitpid($kid,0);
  } else {
    defined (my $grandkid = fork) or die "Kid cannot fork: $!\n";
    if ($grandkid) {
      CORE::exit(0);
    } else {
      # code here
      # do something long lasting
      CORE::exit(0);
    }
  }

Grandkid becomes a "child of init", i.e. the child of the process whose PID is 1.

Note that the previous two solutions do allow you to know the exit status of the process, but in our example we didn't care about it.

Another solution is to use a different SIGCHLD handler:

  use POSIX 'WNOHANG';
  $SIG{CHLD} = sub { while( waitpid(-1,WNOHANG)>0 ) {} };

Which is useful when you fork() more than one process. The handler could call wait() as well, but for a variety of reasons involving the handling of stopped processes and the rare event in which two children exit at nearly the same moment, the best technique is to call waitpid() in a tight loop with a first argument of -1 and a second argument of WNOHANG. Together these arguments tell waitpid() to reap the next child that's available, and prevent the call from blocking if there happens to be no child ready for reaping. The handler will loop until waitpid() returns a negative number or zero, indicating that no more reapable children remain.

While you test and debug your code that uses one of the above examples, You might want to write some debug information to the error_log file so you know what happens.

Read perlipc manpage for more information about signal handlers.



TOP

A Complete Fork Example

Now let's put all the bits of code together and show a well written fork code that solves all the problems discussed so far. We will use an Apache::Registry script for this purpose:

  proper_fork1.pl
  ---------------
  use strict;
  use POSIX 'setsid';
  use Apache::SubProcess;
  
  my $r = shift;
  $r->send_http_header("text/plain");
  
  $SIG{CHLD} = 'IGNORE';
  defined (my $kid = fork) or die "Cannot fork: $!\n";
  if ($kid) {
    print "Parent $$ has finished, kid's PID: $kid\n";
  } else {
      $r->cleanup_for_exec(); # untie the socket
      chdir '/'                or die "Can't chdir to /: $!";
      open STDIN, '/dev/null'  or die "Can't read /dev/null: $!";
      open STDOUT, '>/dev/null'
          or die "Can't write to /dev/null: $!";
      open STDERR, '>/tmp/log' or die "Can't write to /tmp/log: $!";
      setsid or die "Can't start a new session: $!";
  
      my $oldfh = select STDERR;
      local $| = 1;
      select $oldfh;
      warn "started\n";
      # do something time-consuming
      sleep 1, warn "$_\n" for 1..20;
      warn "completed\n";
  
      CORE::exit(0); # terminate the process
  }

The script starts with the usual declaration of the strict mode, loading the POSIX and Apache::SubProcess modules and importing of the setsid() symbol from the POSIX package.

The HTTP header is sent next, with the Content-type of text/plain. The parent process gets ready to ignore the child, to avoid zombies and the fork is called.

The program gets its personality split after fork and the if conditional evaluates to a true value for the parent process, and to a false value for the child process, therefore the first block is executed by the parent and the second by the child.

The parent process announces his PID and the PID of the spawned process and finishes its block. If there will be any code outside it will be executed by the parent as well.

The child process starts its code by disconnecting from the socket, changing its current directory to /, opening the STDIN and STDOUT streams to /dev/null, which in effect closes them both before opening. In fact in this example we don't need neither of these, so we could just close() both. The child process completes its disengagement from the parent process by opening the STDERR stream to /tmp/log, so it could write there, and creating a new session with help of setsid(). Now the child process has nothing to do with the parent process and can do the actual processing that it has to do. In our example it performs a simple series of warnings, which are logged into /tmp/log:

      my $oldfh = select STDERR;
      local $| = 1;
      select $oldfh;
      warn "started\n";
      # do something time-consuming
      sleep 1, warn "$_\n" for 1..20;
      warn "completed\n";

The localized setting of $|=1 unbuffers the STDERR stream, so we can immediately see the debug output generated by the program. In fact this setting is not required when the output is generated by warn().

Finally the child process terminates by calling:

      CORE::exit(0);

which make sure that it won't get out of the block and run some code that it's not supposed to run.

This code example will allow you to verify that indeed the spawned child process has its own life, and its parent is free as well. Simply issue a request that will run this script, watch that the warnings are started to be written into the /tmp/log file and issue a complete server stop and start. If everything is correct, the server will successfully restart and the long term process will still be running. You will know that it's still running, if the warnings will still be printed into the /tmp/log file. You may need to raise the number of warnings to do above 20, to make sure that you don't miss the end of the run.

If there are only 5 warnings to be printed, you should see the following output in this file:

  started
  1
  2
  3
  4
  5
  completed


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Starting a Long Running External Program

But what happens if we cannot just run a Perl code from the spawned process and we have a compiled utility, i.e. a program written in C. Or we have a Perl program which cannot be easily converted into a module, and thus called as a function. Of course in this case we have to use system(), exec(), qx() or `` (back ticks) to start it.

When using any of these methods and when the Taint mode is enabled, we must at least add the following code to untaint the PATH environment variable and delete a few other insecure environment variables. This information can be found in the perlsec manpage.

  $ENV{'PATH'} = '/bin:/usr/bin';
  delete @ENV{'IFS', 'CDPATH', 'ENV', 'BASH_ENV'};

Now all we have to do is to reuse the code from the previous section.

First we move the core program into the external.pl file, add the shebang first line so the program will be executed by Perl, tell the program to run under Taint mode (-T) and possibly enable the warnings mode (-w) and make it executable:

  external.pl
  -----------
  #!/usr/bin/perl -Tw
  
  open STDIN, '/dev/null'  or die "Can't read /dev/null: $!";
  open STDOUT, '>/dev/null'
      or die "Can't write to /dev/null: $!";
  open STDERR, '>/tmp/log' or die "Can't write to /tmp/log: $!";
  
  my $oldfh = select STDERR;
  local $| = 1;
  select $oldfh;
  warn "started\n";
  # do something time-consuming
  sleep 1, warn "$_\n" for 1..20;
  warn "completed\n";

Now we replace the code that moved into the external program with exec() to call it:

  proper_fork_exec.pl
  -------------------
  use strict;
  use POSIX 'setsid';
  use Apache::SubProcess;
  
  $ENV{'PATH'} = '/bin:/usr/bin';
  delete @ENV{'IFS', 'CDPATH', 'ENV', 'BASH_ENV'};
  
  my $r = shift;
  $r->send_http_header("text/html");
  
  $SIG{CHLD} = 'IGNORE';
  
  defined (my $kid = fork) or die "Cannot fork: $!\n";
  if ($kid) {
    print "Parent has finished, kid's PID: $kid\n";
  } else {
      $r->cleanup_for_exec(); # untie the socket
      chdir '/'                or die "Can't chdir to /: $!";
      open STDIN, '/dev/null'  or die "Can't read /dev/null: $!";
      open STDOUT, '>/dev/null'
          or die "Can't write to /dev/null: $!";
      open STDERR, '>&STDOUT'  or die "Can't dup stdout: $!";
      setsid or die "Can't start a new session: $!";
  
      exec "/home/httpd/perl/external.pl" or die "Cannot execute exec: $!";
  }

Notice that exec() never returns unless it fails to start the process. Therefore you shouldn't put any code after exec()--it will be not executed in the case of success. Use system() or back-ticks instead if you want to continue doing other things in the process. But then you probably will want to terminate the process after the program has finished. So you will have to write:

      system "/home/httpd/perl/external.pl" or die "Cannot execute system: $!";
      CORE::exit(0);

Another important nuance is that we have to close all STD* stream in the forked process, even if the called program does that.

If the external program is written in Perl you may pass complicated data structures to it using one of the methods to serialize Perl data and then to restore it. The Storable and FreezeThaw modules come handy. Let's say that we have program master.pl calling program slave.pl:

  master.pl
  ---------
  # we are within the mod_perl code
  use Storable ();
  my @params = (foo => 1, bar => 2);
  my $params = Storable::freeze(\@params);
  exec "./slave.pl", $params or die "Cannot execute exec: $!";

  slave.pl
  --------
  #!/usr/bin/perl -w
  use Storable ();
  my @params = @ARGV ? @{ Storable::thaw(shift)||[] } : ();
  # do something

As you can see, master.pl serializes the @params data structure with Storable::freeze and passes it to slave.pl as a single argument. slave.pl restores the it with Storable::thaw, by shifting the first value of the ARGV array if available. The FreezeThaw module does a very similar thing.



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Starting a Short Running External Program

Sometimes you need to call an external program and you cannot continue before this program completes its run and optionally returns some result. In this case the fork solution doesn't help. But we have a few ways to execute this program. First using system():

  system "perl -e 'print 5+5'"

We believe that you will never call the perl interperter for doing this simple calculation, but for the sake of a simple example it's good enough.

The problem with this approach is that we cannot get the results printed to STDOUT, and that's where back-ticks or qx() come to help. If you use either:

  my $result = `perl -e 'print 5+5'`;

or:

  my $result = qx{perl -e 'print 5+5'};

the whole output of the external program will be stored in the $result variable.

Of course you can use other solutions, like opening a pipe (| to the program) if you need to submit many arguments and more evolved solutions provided by other Perl modules like IPC::Open2 which allows to open a process for both reading and writing.



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Executing system() or exec() in the Right Way

The exec() and system() system calls behave identically in the way they spawn a program. For example let's use system() as an example. Consider the following code:

  system("echo","Hi");

Perl will use the first argument as a program to execute, find /bin/echo along the search path, invoke it directly and pass the Hi string as an argument.

Perl's system() is not the system(3) call [C-library]. This is how the arguments to system() get interpreted. When there is a single argument to system(), it'll be checked for having shell metacharacters first (like *,?), and if there are any--Perl interpreter invokes a real shell program (/bin/sh -c on Unix platforms). If you pass a list of arguments to system(), they will be not checked for metacharacters, but split into words if required and passed directly to the C-level execvp() system call, which is more efficient. That's a very nice optimization. In other words, only if you do:

  system "sh -c 'echo *'"

will the operating system actually exec() a copy of /bin/sh to parse your command. But even then since sh is almost certainly already running somewhere, the system will notice that (via the disk inode reference) and replace your virtual memory page table with one pointing to the existing program code plus your data space, thus will not create this overhead.



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OS Specific Parameters for Proxying

Most of the mod_perl enabled servers use a proxy front-end server. This is done in order to avoid serving static objects, and also so that generated output which might be received by slow clients does not cause the heavy but very fast mod_perl servers from idly waiting.

There are very important OS parameters that you might want to change in order to improve the server performance. This topic is discussed in the section: Setting the Buffering Limits on Various OSes



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Performance Tuning by Tweaking Apache Configuration

Correct configuration of the MinSpareServers, MaxSpareServers, StartServers, MaxClients, and MaxRequestsPerChild parameters is very important. There are no defaults. If they are too low, you will under-use the system's capabilities. If they are too high, the chances are that the server will bring the machine to its knees.

All the above parameters should be specified on the basis of the resources you have. With a plain apache server, it's no big deal if you run many servers since the processes are about 1Mb and don't eat a lot of your RAM. Generally the numbers are even smaller with memory sharing. The situation is different with mod_perl. I have seen mod_perl processes of 20Mb and more. Now if you have MaxClients set to 50: 50x20Mb = 1Gb. Do you have 1Gb of RAM? Maybe not. So how do you tune the parameters? Generally by trying different combinations and benchmarking the server. Again mod_perl processes can be of much smaller size with memory sharing.

Before you start this task you should be armed with the proper weapon. You need the crashme utility, which will load your server with the mod_perl scripts you possess. You need it to have the ability to emulate a multiuser environment and to emulate the behavior of multiple clients calling the mod_perl scripts on your server simultaneously. While there are commercial solutions, you can get away with free ones which do the same job. You can use the ApacheBench ab utility which comes with the Apache distribution, the crashme script which uses LWP::Parallel::UserAgent, httperf or http_load.

It is important to make sure that you run the load generator (the client which generates the test requests) on a system that is more powerful than the system being tested. After all we are trying to simulate Internet users, where many users are trying to reach your service at once. Since the number of concurrent users can be quite large, your testing machine must be very powerful and capable of generating a heavy load. Of course you should not run the clients and the server on the same machine. If you do, your test results would be invalid. Clients will eat CPU and memory that should be dedicated to the server, and vice versa.



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Configuration Tuning with ApacheBench

We are going to use ApacheBench (ab) utility to tune our server's configuration. We will simulate 10 users concurrently requesting a very light script at http://www.example.com/perl/access/access.cgi. Each simulated user makes 10 requests.

  % ./ab -n 100 -c 10 http://www.example.com/perl/access/access.cgi

The results are:

  Document Path:          /perl/access/access.cgi
  Document Length:        16 bytes
  
  Concurrency Level:      10
  Time taken for tests:   1.683 seconds
  Complete requests:      100
  Failed requests:        0
  Total transferred:      16100 bytes
  HTML transferred:       1600 bytes
  Requests per second:    59.42
  Transfer rate:          9.57 kb/s received
  
  Connnection Times (ms)
                min   avg   max
  Connect:        0    29   101
  Processing:    77   124  1259
  Total:         77   153  1360

The only numbers we really care about are:

  Complete requests:      100
  Failed requests:        0
  Requests per second:    59.42

Let's raise the request load to 100 x 10 (10 users, each makes 100 requests):

  % ./ab -n 1000 -c 10  http://www.example.com/perl/access/access.cgi
  Concurrency Level:      10
  Complete requests:      1000
  Failed requests:        0
  Requests per second:    139.76

As expected, nothing changes -- we have the same 10 concurrent users. Now let's raise the number of concurrent users to 50:

  % ./ab -n 1000 -c 50  http://www.example.com/perl/access/access.cgi
  Complete requests:      1000
  Failed requests:        0
  Requests per second:    133.01

We see that the server is capable of serving 50 concurrent users at 133 requests per second! Let's find the upper limit. Using -n 10000 -c 1000 failed to get results (Broken Pipe?). Using -n 10000 -c 500 resulted in 94.82 requests per second. The server's performance went down with the high load.

The above tests were performed with the following configuration:

  MinSpareServers 6
  MaxSpareServers 8
  StartServers 10
  MaxClients 50
  MaxRequestsPerChild 1500

Now let's kill each child after it serves a single request. We will use the following configuration:

  MinSpareServers 6
  MaxSpareServers 8
  StartServers 10
  MaxClients 100
  MaxRequestsPerChild 1

Simulate 50 users each generating a total of 20 requests:

  % ./ab -n 1000 -c 50  http://www.example.com/perl/access/access.cgi

The benchmark timed out with the above configuration.... I watched the output of ps as I ran it, the parent process just wasn't capable of respawning the killed children at that rate. When I raised the MaxRequestsPerChild to 10, I got 8.34 requests per second. Very bad - 18 times slower! You can't benchmark the importance of the MinSpareServers, MaxSpareServers and StartServers with this kind of test.

Now let's reset MaxRequestsPerChild to 1500, but reduce MaxClients to 10 and run the same test:

  MinSpareServers 6
  MaxSpareServers 8
  StartServers 10
  MaxClients 10
  MaxRequestsPerChild 1500

I got 27.12 requests per second, which is better but still 4-5 times slower. (I got 133 with MaxClients set to 50.)

Summary: I have tested a few combinations of the server configuration variables (MinSpareServers, MaxSpareServers, StartServers, MaxClients and MaxRequestsPerChild). The results I got are as follows:

MinSpareServers, MaxSpareServers and StartServers are only important for user response times. Sometimes users will have to wait a bit.

The important parameters are MaxClients and MaxRequestsPerChild. MaxClients should be not too big, so it will not abuse your machine's memory resources, and not too small, for if it is your users will be forced to wait for the children to become free to serve them. MaxRequestsPerChild should be as large as possible, to get the full benefit of mod_perl, but watch your server at the beginning to make sure your scripts are not leaking memory, thereby causing your server (and your service) to die very fast.

Also it is important to understand that we didn't test the response times in the tests above, but the ability of the server to respond under a heavy load of requests. If the test script was heavier, the numbers would be different but the conclusions very similar.

The benchmarks were run with:

  HW: RS6000, 1Gb RAM
  SW: AIX 4.1.5 . mod_perl 1.16, apache 1.3.3
  Machine running only mysql, httpd docs and mod_perl servers.
  Machine was _completely_ unloaded during the benchmarking.

After each server restart when I changed the server's configuration, I made sure that the scripts were preloaded by fetching a script at least once for every child.

It is important to notice that none of the requests timed out, even if it was kept in the server's queue for more than a minute! That is the way ab works, which is OK for testing purposes but will be unacceptable in the real world - users will not wait for more than five to ten seconds for a request to complete, and the client (i.e. the browser) will time out in a few minutes.

Now let's take a look at some real code whose execution time is more than a few milliseconds. We will do some real testing and collect the data into tables for easier viewing.

I will use the following abbreviations:

  NR    = Total Number of Request
  NC    = Concurrency
  MC    = MaxClients
  MRPC  = MaxRequestsPerChild
  RPS   = Requests per second

Running a mod_perl script with lots of mysql queries (the script under test is mysqld limited) (http://www.example.com/perl/access/access.cgi?do_sub=query_form), with the configuration:

  MinSpareServers    8
  MaxSpareServers   16
  StartServers      10
  MaxClients        50
  MaxRequestsPerChild 5000

gives us:

     NR   NC    RPS comment
  ------------------------------------------------
     10   10    3.33    # not a reliable figure
    100   10    3.94    
   1000   10    4.62    
   1000   50    4.09

Conclusions: Here I wanted to show that when the application is slow (not due to perl loading, code compilation and execution, but limited by some external operation) it almost does not matter what load we place on the server. The RPS (Requests per second) is almost the same. Given that all the requests have been served, you have the ability to queue the clients, but be aware that anything that goes into the queue means a waiting client and a client (browser) that might time out!

Now we will benchmark the same script without using the mysql (code limited by perl only): (http://www.example.com/perl/access/access.cgi), it's the same script but it just returns the HTML form, without making SQL queries.

  MinSpareServers    8
  MaxSpareServers   16
  StartServers      10
  MaxClients        50
  MaxRequestsPerChild 5000

     NR   NC      RPS   comment
  ------------------------------------------------
     10   10    26.95   # not a reliable figure
    100   10    30.88   
   1000   10    29.31
   1000   50    28.01
   1000  100    29.74
  10000  200    24.92
 100000  400    24.95

Conclusions: This time the script we executed was pure perl (not limited by I/O or mysql), so we see that the server serves the requests much faster. You can see the number of requests per second is almost the same for any load, but goes lower when the number of concurrent clients goes beyond MaxClients. With 25 RPS, the machine simulating a load of 400 concurrent clients will be served in 16 seconds. To be more realistic, assuming a maximum of 100 concurrent clients and 30 requests per second, the client will be served in 3.5 seconds. Pretty good for a highly loaded server.

Now we will use the server to its full capacity, by keeping all MaxClients clients alive all the time and having a big MaxRequestsPerChild, so that no child will be killed during the benchmarking.

  MinSpareServers   50
  MaxSpareServers   50
  StartServers      50
  MaxClients        50
  MaxRequestsPerChild 5000
  
     NR   NC      RPS   comment
  ------------------------------------------------
    100   10    32.05
   1000   10    33.14
   1000   50    33.17
   1000  100    31.72
  10000  200    31.60

Conclusion: In this scenario there is no overhead involving the parent server loading new children, all the servers are available, and the only bottleneck is contention for the CPU.

Now we will change MaxClients and watch the results: Let's reduce MaxClients to 10.

  MinSpareServers    8
  MaxSpareServers   10
  StartServers      10
  MaxClients        10
  MaxRequestsPerChild 5000
  
     NR   NC      RPS   comment
  ------------------------------------------------
     10   10    23.87   # not a reliable figure
    100   10    32.64 
   1000   10    32.82
   1000   50    30.43
   1000  100    25.68
   1000  500    26.95
   2000  500    32.53

Conclusions: Very little difference! Ten servers were able to serve almost with the same throughput as 50 servers. Why? My guess is because of CPU throttling. It seems that 10 servers were serving requests 5 times faster than when we worked with 50 servers. In that case, each child received its CPU time slice five times less frequently. So having a big value for MaxClients, doesn't mean that the performance will be better. You have just seen the numbers!

Now we will start drastically to reduce MaxRequestsPerChild:

  MinSpareServers    8
  MaxSpareServers   16
  StartServers      10
  MaxClients        50

     NR   NC    MRPC     RPS    comment
  ------------------------------------------------
    100   10      10    5.77 
    100   10       5    3.32
   1000   50      20    8.92
   1000   50      10    5.47
   1000   50       5    2.83
   1000  100      10    6.51

Conclusions: When we drastically reduce MaxRequestsPerChild, the performance starts to become closer to plain mod_cgi.

Here are the numbers of this run with mod_cgi, for comparison:

  MinSpareServers    8
  MaxSpareServers   16
  StartServers      10
  MaxClients        50
  
     NR   NC    RPS comment
  ------------------------------------------------
    100   10    1.12
   1000   50    1.14
   1000  100    1.13

Conclusion: mod_cgi is much slower. :) In the first test, when NR/NC was 100/10, mod_cgi was capable of 1.12 requests per second. In the same circumstances, mod_perl was capable of 32 requests per second, nearly 30 times faster! In the first test each client waited about 100 seconds to be served. In the second and third tests they waited 1000 seconds!



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Choosing MaxClients

The MaxClients directive sets the limit on the number of simultaneous requests that can be supported. No more than this number of child server processes will be created. To configure more than 256 clients, you must edit the HARD_SERVER_LIMIT entry in httpd.h and recompile. In our case we want this variable to be as small as possible, because in this way we can limit the resources used by the server children. Since we can restrict each child's process size (see Preventing Your Processes from Growing), the calculation of MaxClients is pretty straightforward:

               Total RAM Dedicated to the Webserver
  MaxClients = ------------------------------------
                     MAX child's process size

So if I have 400Mb left for the webserver to run with, I can set MaxClients to be of 40 if I know that each child is limited to 10Mb of memory (e.g. with Apache::SizeLimit).

You will be wondering what will happen to your server if there are more concurrent users than MaxClients at any time. This situation is signified by the following warning message in the error_log:

  [Sun Jan 24 12:05:32 1999] [error] server reached MaxClients setting,
  consider raising the MaxClients setting

There is no problem -- any connection attempts over the MaxClients limit will normally be queued, up to a number based on the ListenBacklog directive. When a child process is freed at the end of a different request, the connection will be served.

It is an error because clients are being put in the queue rather than getting served immediately, despite the fact that they do not get an error response. The error can be allowed to persist to balance available system resources and response time, but sooner or later you will need to get more RAM so you can start more child processes. The best approach is to try not to have this condition reached at all, and if you reach it often you should start to worry about it.

It's important to understand how much real memory a child occupies. Your children can share memory between them when the OS supports that. You must take action to allow the sharing to happen - See Preload Perl modules at server startup. If you do this, the chances are that your MaxClients can be even higher. But it seems that it's not so simple to calculate the absolute number. If you come up with a solution please let us know! If the shared memory was of the same size throughout the child's life, we could derive a much better formula:

               Total_RAM + Shared_RAM_per_Child * (MaxClients - 1)
  MaxClients = ---------------------------------------------------
                              Max_Process_Size

which is:

                    Total_RAM - Shared_RAM_per_Child
  MaxClients = ---------------------------------------
               Max_Process_Size - Shared_RAM_per_Child

Let's roll some calculations:

  Total_RAM            = 500Mb
  Max_Process_Size     =  10Mb
  Shared_RAM_per_Child =   4Mb

              500 - 4
 MaxClients = --------- = 82
               10 - 4

With no sharing in place

                 500
  MaxClients = --------- = 50
                 10

With sharing in place you can have 64% more servers without buying more RAM.

If you improve sharing and keep the sharing level, let's say:

  Total_RAM            = 500Mb
  Max_Process_Size     =  10Mb
  Shared_RAM_per_Child =   8Mb
 
               500 - 8
  MaxClients = --------- = 246
                10 - 8

392% more servers! Now you can feel the importance of having as much shared memory as possible.



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Choosing MaxRequestsPerChild

The MaxRequestsPerChild directive sets the limit on the number of requests that an individual child server process will handle. After MaxRequestsPerChild requests, the child process will die. If MaxRequestsPerChild is 0, then the process will live forever.

Setting MaxRequestsPerChild to a non-zero limit solves some memory leakage problems caused by sloppy programming practices, whereas a child process consumes more memory after each request.

If left unbounded, then after a certain number of requests the children will use up all the available memory and leave the server to die from memory starvation. Note that sometimes standard system libraries leak memory too, especially on OSes with bad memory management (e.g. Solaris 2.5 on x86 arch).

If this is your case you can set MaxRequestsPerChild to a small number. This will allow the system to reclaim the memory that a greedy child process consumed, when it exits after MaxRequestsPerChild requests.

But beware -- if you set this number too low, you will lose some of the speed bonus you get from mod_perl. Consider using Apache::PerlRun if this is the case.

Another approach is to use the Apache::SizeLimit or Apache::GTopLimit modules. By using either of these modules you should be able to discontinue using the MaxRequestPerChild, although for some developers, using both in combination does the job. In addition these modules allow you to kill httpd processes whose shared memory size drops below a specified limit or unshared memory size crosses a specified threshold.

See also Preload Perl modules at server startup and Sharing Memory.



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Choosing MinSpareServers, MaxSpareServers and StartServers

With mod_perl enabled, it might take as much as 20 seconds from the time you start the server until it is ready to serve incoming requests. This delay depends on the OS, the number of preloaded modules and the process load of the machine. It's best to set StartServers and MinSpareServers to high numbers, so that if you get a high load just after the server has been restarted the fresh servers will be ready to serve requests immediately. With mod_perl, it's usually a good idea to raise all 3 variables higher than normal.

In order to maximize the benefits of mod_perl, you don't want to kill servers when they are idle, rather you want them to stay up and available to handle new requests immediately. I think an ideal configuration is to set MinSpareServers and MaxSpareServers to similar values, maybe even the same. Having the MaxSpareServers close to MaxClients will completely use all of your resources (if MaxClients has been chosen to take the full advantage of the resources), but it'll make sure that at any given moment your system will be capable of responding to requests with the maximum speed (assuming that number of concurrent requests is not higher than MaxClients).

Let's try some numbers. For a heavily loaded web site and a dedicated machine I would think of (note 400Mb is just for example):

  Available to webserver RAM:   400Mb
  Child's memory size bounded:  10Mb
  MaxClients:           400/10 = 40 (larger with mem sharing)
  StartServers:         20
  MinSpareServers:      20
  MaxSpareServers:      35

However if I want to use the server for many other tasks, but make it capable of handling a high load, I'd think of:

  Available to webserver RAM:   400Mb
  Child's memory size bounded:  10Mb
  MaxClients:           400/10 = 40
  StartServers:         5
  MinSpareServers:      5
  MaxSpareServers:      10

These numbers are taken off the top of my head, and shouldn't be used as a rule, but rather as examples to show you some possible scenarios. Use this information with caution!



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Summary of Benchmarking to tune all 5 parameters

OK, we've run various benchmarks -- let's summarize the conclusions:



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KeepAlive

If your mod_perl server's httpd.conf includes the following directives:

  KeepAlive On
  MaxKeepAliveRequests 100
  KeepAliveTimeout 15

you have a real performance penalty, since after completing the processing for each request, the process will wait for KeepAliveTimeout seconds before closing the connection and will therefore not be serving other requests during this time. With this configuration you will need many more concurrent processes on a server with high traffic.

If you use some server status reporting tools, you will see the process in K status when it's in KeepAlive status.

The chances are that you don't want this feature enabled. Set it Off with:

  KeepAlive Off

the other two directives don't matter if KeepAlive is Off.

You might want to consider enabling this option if the client's browser needs to request more than one object from your server for a single HTML page. If this is the situation the by setting KeepAlive On then for each page you save the HTTP connection overhead for all requests but the first one.

For example if you have a page with 10 ad banners, which is not uncommon today, you server will work more effectively if a single process serves them all during a single connection. However, your client will see a slightly slower response, since banners will be brought one at a time and not concurrently as is the case if each IMG tag opens a separate connection.

Since keepalive connections will not incur the additional three-way TCP handshake they are kinder to the network.

SSL connections benefit the most from KeepAlive in case you didn't configure the server to cache session ids.

You have probably followed the advice to send all the requests for static objects to a plain Apache server. Since most pages include more than one unique static image, you should keep the default KeepAlive setting of the non-mod_perl server, i.e. keep it On. It will probably be a good idea also to reduce the timeout a little.

One option would be for the proxy/accelerator to keep the connection open to the client but make individual connections to the server, read the response, buffer it for sending to the client and close the server connection. Obviously you would make new connections to the server as required by the client's requests.



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PerlSetupEnv Off

PerlSetupEnv Off is another optimization you might consider. This directive requires mod_perl 1.25 or later.

When this option is enabled, mod_perl fiddles with the environment to make it appear as if the code is called under the mod_cgi handler. For example, the $ENV{QUERY_STRING} environment variable is initialized with the contents of Apache::args(), and the value returned by Apache::server_hostname() is put into $ENV{SERVER_NAME}.

But %ENV population is expensive. Those who have moved to the Perl Apache API no longer need this extra %ENV population, and can gain by turning it Off. Scripts using the CGI.pm module require PerlSetupEnv On because that module relies on a properly populated CGI environment table.

By default it is turned On.

Note that you can still set enviroment variables when PerlSetupEnv is turned Off. For example when you use the following configuration:

  PerlSetupEnv Off
  PerlModule Apache::RegistryNG
  <Location /perl>
    PerlSetEnv TEST hi
    SetHandler perl-script
    PerlHandler Apache::RegistryNG
    Options +ExecCGI
  </Location>

and you issue a request for this script:

  setupenvoff.pl
  --------------
  use Data::Dumper;
  my $r = Apache->request();
  $r->send_http_header('text/plain');
  print Dumper(\%ENV);

you should see something like this:

  $VAR1 = {
            'GATEWAY_INTERFACE' => 'CGI-Perl/1.1',
            'MOD_PERL' => 'mod_perl/1.25',
            'PATH' => '/usr/lib/perl5/5.00503:... snipped ...',
            'TEST' => 'hi'
          };

Note that we got the value of the TEST environment variable we set in httpd.conf.



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Reducing the Number of stat() Calls Made by Apache

If you watch the system calls that your server makes (using truss or strace while processing a request, you will notice that a few stat() calls are made. For example when I fetch http://localhost/perl-status and I have my DocRoot set to /home/httpd/docs I see:

  [snip]
  stat("/home/httpd/docs/perl-status", 0xbffff8cc) = -1 
                      ENOENT (No such file or directory)
  stat("/home/httpd/docs", {st_mode=S_IFDIR|0755, 
                                 st_size=1024, ...}) = 0
  [snip]

If you have some dynamic content and your virtual relative URI is something like /news/perl/mod_perl/summary (i.e., there is no such directory on the web server, the path components are only used for requesting a specific report), this will generate five(!) stat() calls, before the DocumentRoot is found. You will see something like this:

  stat("/home/httpd/docs/news/perl/mod_perl/summary", 0xbffff744) = -1 
                      ENOENT (No such file or directory)
  stat("/home/httpd/docs/news/perl/mod_perl",         0xbffff744) = -1
                      ENOENT (No such file or directory)
  stat("/home/httpd/docs/news/perl",                  0xbffff744) = -1
                      ENOENT (No such file or directory)
  stat("/home/httpd/docs/news",                       0xbffff744) = -1
                      ENOENT (No such file or directory)
  stat("/home/httpd/docs", 
                      {st_mode=S_IFDIR|0755, st_size=1024, ...})  =  0

How expensive those calls are? Let's use the Time::HiRes module to find out.

  stat_call_sample.pl
  -------------------
  use Time::HiRes qw(gettimeofday tv_interval);
  my $calls = 1_000_000;
  
  my $start_time = [ gettimeofday ];
  
  stat "/foo" for 1..$calls;
  
  my $end_time = [ gettimeofday ];
  
  my $elapsed = tv_interval($start_time,$end_time) / $calls;
  
  print "The average execution time: $elapsed seconds\n";

This script takes a time sample at the beginnig, then does 1_000_000 stat() calls to a non-existing file, samples the time at the end and prints the average time it took to make a single stat() call. I'm sampling a 1M stats, so I'd get a correct average result.

Before we actually run the script one should distinguish between two different situation. When the server is idle the time between the first and the last system call will be much shorter than the same time measured on the loaded system. That is because on the idle system, a process can use CPU very often, and on the loaded system lots of processes compete over it and each process has to wait for a longer time to get the same amount of CPU time.

So first we run the above code on the unloaded system:

  % perl stat_call_sample.pl
  The average execution time: 4.209645e-06 seconds

So it takes about 4 microseconds to execute a stat() call. Now let start a CPU intensive process in one console. The following code keeps CPU busy all the time.

  % perl -e '1**1 while 1'

And now run the stat_call_sample.pl script in the other console.

  % perl stat_call_sample.pl
  The average execution time: 8.777301e-06 seconds

You can see that the average time has doubled (about 8 microseconds). And this is obvious, since there were two processes competing over CPU. Now if run 4 occurrences of the above code:

  % perl -e '1**1 while 1' &
  % perl -e '1**1 while 1' &
  % perl -e '1**1 while 1' &
  % perl -e '1**1 while 1' &

And when running our script in parallel with these processes, we get:

  % perl stat_call_sample.pl
  2.0853558e-05 seconds

about 20 microseconds. So the average stat() system call is 5 times longer now. Now if you have 50 mod_perl processes that keep the CPU busy all the time, the stat() call will be 50 times slower and it'll take 0.2 milliseconds to complete a series of call. If you have five redundant calls as in the strace example above, they adds up to one millisecond. If you have more processes constantly consuming CPU, this time adds up. Now multiply this time by the number of processes that you have and you get a few seconds lost. As usual, for some services this loss is insignificant, while for others a very significant one.

So why Apache does all these redundant stat() calls? You can blame the default installed TransHandler for this inefficiency. Of course you could supply your own, which will be smart enough not to look for this virtual path and immediately return OK. But in cases where you have a virtual host that serves only dynamically generated documents, you can override the default PerlTransHandler with this one:

  PerlModule Apache::Constants
  <VirtualHost 10.10.10.10:80>
    ...
    PerlTransHandler  Apache::Constants::OK
    ...
  </VirtualHost>

As you see it affects only this specific virtual host.

This has the effect of short circuiting the normal TransHandler processing of trying to find a filesystem component that matches the given URI -- no more 'stat's!

Watching your server under strace/truss can often reveal more performance hits than trying to optimize the code itself!

For example unless configured correctly, Apache might look for the .htaccess file in many places, if you don't have one and add many open() calls.

Let's start with this simple configuration, and will try to reduce the number of irrelevant system calls.

  DocumentRoot "/home/httpd/docs"
  <Location /foo/test>
    SetHandler perl-script
    PerlHandler Apache::Foo
  </Location>

The above configuration allows us to make a request to /foo/test and the Perl handler() defined in Apache::Foo will be executed. Notice that in the test setup there is no file to be executed (like in Apache::Registry). There is no .htaccess file as well.

This is a typical generated trace.

  stat("/home/httpd/docs/foo/test", 0xbffff8fc) = -1 ENOENT 
    (No such file or directory)
  stat("/home/httpd/docs/foo",      0xbffff8fc) = -1 ENOENT 
    (No such file or directory)
  stat("/home/httpd/docs", 
    {st_mode=S_IFDIR|0755, st_size=1024, ...}) = 0
  open("/.htaccess", O_RDONLY)                 = -1 ENOENT 
    (No such file or directory)
  open("/home/.htaccess", O_RDONLY)            = -1 ENOENT 
    (No such file or directory)
  open("/home/httpd/.htaccess", O_RDONLY)      = -1 ENOENT 
    (No such file or directory)
  open("/home/httpd/docs/.htaccess", O_RDONLY) = -1 ENOENT 
    (No such file or directory)
  stat("/home/httpd/docs/test", 0xbffff774)    = -1 ENOENT 
    (No such file or directory)
  stat("/home/httpd/docs", 
    {st_mode=S_IFDIR|0755, st_size=1024, ...}) = 0

Now we modify the <Directory> entry and add AllowOverride None, which among other things disables .htaccess files and will not try to open them.

  <Directory />
    AllowOverride None
  </Directory>

We see that the four open() calls for .htaccess have gone.

  stat("/home/httpd/docs/foo/test", 0xbffff8fc) = -1 ENOENT 
    (No such file or directory)
  stat("/home/httpd/docs/foo",      0xbffff8fc) = -1 ENOENT 
    (No such file or directory)
  stat("/home/httpd/docs", 
    {st_mode=S_IFDIR|0755, st_size=1024, ...}) = 0
  stat("/home/httpd/docs/test", 0xbffff774)    = -1 ENOENT 
    (No such file or directory)
  stat("/home/httpd/docs", 
    {st_mode=S_IFDIR|0755, st_size=1024, ...}) = 0

Let's try to shortcut the foo location with:

  Alias /foo /

Which makes Apache to look for the file in the / directory and not under /home/httpd/docs/foo. Let's run it:

  stat("//test", 0xbffff8fc) = -1 ENOENT (No such file or directory)

Wow, we've got only one stat call left!

Let's remove the last Alias setting and use:

    PerlModule Apache::Constants
    PerlTransHandler  Apache::Constants::OK

as explained above. When we issue the request, we see no stat() calls. But this is possible only if you serve only dynamically generated documents, i.e. no CGI scripts. Otherwise you will have to write your own PerlTransHandler to handle requests as desired.

For example this PerlTransHandler will not lookup the file on the filesystem if the URI starts with /foo, but will use the default PerlTransHandler otherwise:

  PerlTransHandler 'sub { return shift->uri() =~ m|^/foo| \
                        ? Apache::Constants::OK \
                        : Apache::Constants::DECLINED; }'

Let's see the same configuration using the <Perl> section and a dedicated package:

  <Perl>  
    package My::Trans;
    use Apache::Constants qw(:common);
    sub handler{
       my $r = shift;
       return OK if $r->uri() =~ m|^/foo|;
       return DECLINED;
    }

    package Apache::ReadConfig;  
    $PerlTransHandler = "My::Trans";
  </Perl>

As you see we have defined the My::Trans package and implemented the handler() function. Then we have assigned this handler to the PerlTransHandler.

Of course you can move the code in the module into an external file, (e.g. My/Trans.pm) and configure the PerlTransHandler with

  PerlTransHandler My::Trans

in the normal way (no <Perl> section required).

There is an even simpler way to save that last stat() call. Instead of using PerlTransHandler combined with:

  Alias /foo /

we can use:

  AliasMatch ^/foo /

which in the current implementation (at least in apache-1.3.28) doesn't incur the stat() call. Using the regex instead of prefix matching might slow things a bit, but is probably still faster than the stat() call.



TOP

TMTOWTDI: Convenience and Habit vs. Performance

TMTOWTDI (sometimes pronounced "tim toady"), or "There's More Than One Way To Do It" is the main motto of Perl. In other words, you can gain the same goal by coding in many different styles, using different modules and deploying the same modules in different ways.

Unfortunately when you come to the point where performance is the goal, you might have to learn what's more efficient and what's not. Of course it might mean that you will have to use something that you don't really like, it might be less convenient or it might be just a matter of habit that one should change.

So this section is about performance trade-offs. For almost each comparison we will provide the theoretical difference and then run benchmarks to support the theory, since however good the theory its the numbers we get in practice that matter.

"Premature optimizations are evil", the saying goes. I believe that knowing how to write an efficient code in first place, where it doesn't make the quality and clarity suffer saves time in the long run. That's what this section is mostly about.

In the following benchmarks, unless told different the following Apache configuration has been used:

  MinSpareServers 10
  MaxSpareServers 20
  StartServers 10
  MaxClients 20
  MaxRequestsPerChild 10000


TOP

Apache::Registry PerlHandler vs. Custom PerlHandler

At some point you have to decide whether to use Apache::Registry and similar handlers and stick to writing scripts for the content generation or to write pure Perl handlers.

Apache::Registry maps a request to a file and generates a subroutine to run the code contained in that file. If you use a PerlHandler My::Handler instead of Apache::Registry, you have a direct mapping from request to subroutine, without the steps in between. These steps include:

  1. run the stat() on the script's filename ($r->filename)

  2. check that the file exists and is executable

  3. generate a Perl package name based on the request's URI ($r->uri)

  4. go to the directory the script resides in (chdir basename $r->filename)

  5. compare the file's and stored in memory compiled subroutine's last modified time (if it was compiled already)

  6. if modified or not compiled, compile the subroutine

  7. go back to the previous directory (chdir $old_cwd)

If you cut out those steps, you cut out some overhead, plain and simple. Do you need to cut out that overhead? May be yes, may be not. Your requirements determine that.

You should take a look at the sister Apache::Registry modules (e.g. Apache::RegistryNG and Apache::RegistryBB) that don't perform all these steps, so you can still choose to stick to using scripts to generate the content. The greatest added value of scripts is that you don't have to modify the configuration file to add the handler configuration and restarting the server for each newly written content handler.

Now let's run benchmarks and compare.

We want to see the overhead that Apache::Registry adds compared to the custom handler and whether it becomes insignificant when used for the heavy and time consuming code. In order to do that we will run two benchmarks sets: the first so called a light set will use an almost empty script, that only sends a basic header and one word as content; the second will be a heavy set which will add some time consuming operation to the script's and the handler's code.

For the light set we are going to use the registry.pl script running under Apache::Registry:

  benchmarks/registry.pl
  ----------------------
  use strict;
  print "Content-type: text/plain\r\n\r\n";
  print "Hello";

And the following content generation handler:

  Benchmark/Handler.pm
  --------------------
  package Benchmark::Handler;
  use Apache::Constants qw(:common);
  
  sub handler{
    $r = shift;
    $r->send_http_header('text/html');
    $r->print("Hello");
    return OK;
  }
  1;

We will add this settings to httpd.conf:

  PerlModule Benchmark::Handler
  <Location /benchmark_handler>
    SetHandler perl-script
    PerlHandler Benchmark::Handler
  </Location>

The first directive worries to preload and compile the Benchmark::Handler module. The rest of the lines tell Apache to execute the subroutine Benchmark::Handler::handler when a request with relative URI /benchmark_handler is made.

We will use the usual configuration for Apache::Registry scripts, where all the URIs starting with /perl are remapped to the files residing under /home/httpd/perl/ directory.

  Alias /perl/ /home/httpd/perl/
  <Location /perl>
    SetHandler perl-script
    PerlHandler +Apache::Registry
    Options ExecCGI
    PerlSendHeader On
  </Location>

We will use the Apache::RegistryLoader to preload and compile the script at the server startup as well, so the benchmark will be fair through the benchmark and only the processing time will be measured. To accomplish the preloading we add the following code to the startup.pl file:

  use Apache::RegistryLoader ();
  Apache::RegistryLoader->new->handler(
              "/perl/benchmarks/registry.pl",
   "/home/httpd/perl/benchmarks/registry.pl");

To create the heavy benchmark set let's leave the above code examples unmodified but add some CPU intensive processing operation (it can be also an IO operation or a database query.)

  my $x = 100;
  my $y = log ($x ** 100)  for (0..10000);

This code does lots of mathematical processing and therefore very CPU intensive.

Now we are ready to proceed with the benchmark. We will generate 5000 requests with 15 as a concurrency level using the Apache::Benchmark module.

Here are the reported results:

  ------------------------------
      name        | avtime   rps
  ------------------------------
  light handler   |     15   911
  light registry  |     21   680
  ------------------------------
  heavy handler   |    183    81
  heavy registry  |    191    77
  ------------------------------

Let's look at the results and answer the previously asked questions.

First let's compare the results from the light set. We can see that the average overhead added by Apache::Registry (compared to the custom handler) is about:

  21 - 15 = 6 milliseconds

per request.

Thus the difference in speed is about 40% (15 vs. 21). Note that this doesn't mean that the difference in the real world applications is such big. And the results of the heavy set confirm that.

In the heavy set the average processing time is almost the same for the Apache::Registry and the custom handler. You can clearly see that the difference between the two is almost the same one that we have seen in the light set's results. It has grown from 6 milliseconds to 8 milliseconds (191-183). Which means that the identical heavy code that has been added was running for about 168 milliseconds (183-15). It doesn't mean that the added code itself has been running for 168 milliseconds. It means that it took 168 milliseconds for this code to be completed in a multi-process environment where each process gets a time slice to use the CPU. The more processes are running the more time the process will have to wait to get the next time slice when it can use the CPU.

We have the second question answered as well. You can see that when the code is not just the hello script, the overhead of the extra operations done but the Apache::Registry module, is almost insignificant. It's a non zero though, so it depends on your requirements, and if another 5-10 millisecons overhead are quite tolerable, you may choose to use Apache::Registry.

The interesting thing is that when the server under test runs on a very slow machine the results are completely different. I'll present them here for comparison:

  ------------------------------
      name        | avtime   rps
  ------------------------------
  light handler   |     50   196
  light registry  |    160    61
  ------------------------------
  heavy handler   |    149    67
  heavy registry  |    822    12
  ------------------------------

First of all the difference of 6 milliseconds in the average processing time we have seen on the fast machine when running the light set, now has grown to 110 milliseconds. Which means that a few extra operations, that Apache::Registry does, turn to be very expensive on the slow machine.

Second, you can see that when the heavy set is used, there is no preservation of the 110 milliseconds as we have seen on the fast machine, which we obviously would expect to see, since the code that was added should take the same time to execute in the handler and the script. But instead we see a difference of 673 milliseconds (822-149).

The explanation lies in fact that the difference between the machines isn't merely in the CPU speed. It's possible that there are many other things that are different. For example the size of the processor cache. If one machine has a processor cache large enough to hold the whole handler and the other doesn't this can be very significant, given that in our heavy benchmark set, 99.9% of the CPU activity was dedicated to running the calculation code.

But this also shows you again, that none of the results and conclusion made here should be taken for granted. Certainly, most chances are that you will see a similar behavior on your machine, but only after you have run the benchmarks and analyzed the received results, you can be sure what is the best for you using the setup under test. If you later you happen to use a different machine, make sure to run the tests again, as they can lead to complete different decision as we have just seen when we have tried the same benchmark on a different machine.



TOP

"Bloatware" modules

Perl modules like IO:: are very convenient, but let's see what it costs us to use them. (perl5.6.0 over OpenBSD)

  % wc `perl -MIO -e 'print join("\n", sort values %INC, "")'`
   124     696    4166 /usr/local/lib/perl5/5.6.0/Carp.pm
   580    2465   17661 /usr/local/lib/perl5/5.6.0/Class/Struct.pm
   400    1495   10455 /usr/local/lib/perl5/5.6.0/Cwd.pm
   313    1589   10377 /usr/local/lib/perl5/5.6.0/Exporter.pm
   225     784    5651 /usr/local/lib/perl5/5.6.0/Exporter/Heavy.pm
    92     339    2813 /usr/local/lib/perl5/5.6.0/File/Spec.pm
   442    1574   10276 /usr/local/lib/perl5/5.6.0/File/Spec/Unix.pm
   115     398    2806 /usr/local/lib/perl5/5.6.0/File/stat.pm
   406    1350   10265 /usr/local/lib/perl5/5.6.0/IO/Socket/INET.pm
   143     429    3075 /usr/local/lib/perl5/5.6.0/IO/Socket/UNIX.pm
  7168   24137  178650 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/Config.pm
   230    1052    5995 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/Errno.pm
   222     725    5216 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/Fcntl.pm
    47     101     669 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/IO.pm
   239     769    5005 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/IO/Dir.pm
   169     549    3956 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/IO/File.pm
   594    2180   14772 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/IO/Handle.pm
   252     755    5375 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/IO/Pipe.pm
    77     235    1709 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/IO/Seekable.pm
   428    1419   10219 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/IO/Socket.pm
   452    1401   10554 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/Socket.pm
   127     473    3554 /usr/local/lib/perl5/5.6.0/OpenBSD.i386-openbsd/XSLoader.pm
    52     161    1050 /usr/local/lib/perl5/5.6.0/SelectSaver.pm
   139     541    3754 /usr/local/lib/perl5/5.6.0/Symbol.pm
   161     609    4081 /usr/local/lib/perl5/5.6.0/Tie/Hash.pm
   109     390    2479 /usr/local/lib/perl5/5.6.0/strict.pm
    79     370    2589 /usr/local/lib/perl5/5.6.0/vars.pm
   318    1124   11975 /usr/local/lib/perl5/5.6.0/warnings.pm
    30      85     722 /usr/local/lib/perl5/5.6.0/warnings/register.pm
 13733   48195  349869 total

Moreover, that requires 116 happy trips through the kernel's namei(). It syscalls open() a remarkable 57 times, 17 of which failed but leaving 38 that were successful. It also syscalled read() a curiously identical 57 times, ingesting a total of 180,265 plump bytes. To top it off, this increases your resident set size by two megabytes!

Happy mallocking...

It seems that CGI.pm suffers from the same disease:

  % wc `perl -MCGI -le 'print for values %INC'`
  1368    6920   43710 /usr/local/lib/perl5/5.6.0/overload.pm
  6481   26122  200840 /usr/local/lib/perl5/5.6.0/CGI.pm
  7849   33042  244550 total

You have 16 trips through namei, 7 successful opens, 2 unsuccessful ones, and 213k of data read in.

This is a perlbloat.pl that shows how much memory is acquired by Perl when you run some. So we can easily test the overhead of loading some modules.

  #!/usr/bin/perl -w
  
  use GTop ();
  
  my $gtop = GTop->new;
  my $before = $gtop->proc_mem($$)->size;
  
  for (@ARGV) {
      if (eval "require $_") {
          eval {
              $_->import;
          };
      }
      else {
          eval $_;
          die $@ if $@;
      }
  }
  
  my $after = $gtop->proc_mem($$)->size;
  printf "@ARGV added %s\n", GTop::size_string($after - $before);

Now let's try to load IO, which loads IO::Handle, IO::Seekable, IO::File, IO::Pipe, IO::Socket and IO::Dir:

  % ./perlbloat.pl 'use IO;'
  use IO; added  1.5M

"Only" 1.5 MB overhead. Now let's load CGI (v2.74) and compile all its methods:

  % ./perlbloat.pl 'use CGI; CGI->compile(":all")'
  use CGI; CGI->compile(":all") added  1.8M

Almost 2MB extra memory. Let's compare CGI.pm with its younger sister, whose internals are implemented in C.

  %. /perlbloat.pl 'use Apache::Request'
  use Apache::Request added   48k

48KB. A significant difference isn't it?

The following numbers show memory sizes in KB (virtual and resident) for v5.6.0 of Perl on four different operating systems, The three calls each are without any modules, with just -MCGI, and with -MIO (never with both):

              OpenBSD       FreeBSD    Redhat Linux    Solaris
              vsz   rss     vsz  rss     vsz  rss    vsz    rss
  Raw Perl    736   772     832 1208    2412  980    2928  2272
  w/ CGI     1220  1464    1308 1828    2972 1768    3616  3232
  w/ IO      2292  2580    2456 3016    4080 2868    5384  4976

Anybody who's thinking of choosing one of these might do well to digest these numbers first.



TOP

Apache::args vs. Apache::Request::param vs. CGI::param

Apache::args, Apache::Request::param and CGI::param are the three most common ways to process input arguments in mod_perl handlers and scripts. Let's write three Apache::Registry scripts that use Apache::args, Apache::Request::param and CGI::param to process a form's input and print it out. Notice that Apache::args is considered identical to Apache::Request::param only when you have single valued keys. In the case of multi-valued keys (e.g. when using check-box groups) you will have to write some extra code: If you do a simple:

  my %params = $r->args;

only the last value will be stored and the rest will collapse, because that's what happens when you turn a list into a hash. Assuming that you have the following list:

  (rules => 'Apache', rules => 'Perl', rules => 'mod_perl')

and assign it to a hash, the following happens:

  $hash{rules} = 'Apache';
  $hash{rules} = 'Perl';
  $hash{rules} = 'mod_perl';

So at the end only the:

  rules => 'mod_perl'

pair will get stored. With CGI.pm or Apache::Request you can solve this by extracting the whole list by its key:

  my @values = $q->params('rules');

In addition Apache::Request and CGI.pm have many more functions that ease input processing, like handling file uploads. However Apache::Request is much faster since its guts are implemented in C, glued to Perl using XS code.

Assuming that the only functionality you need is the parsing of key-value pairs, and assuming that every key has a single value, we will compare the following almost identical scripts, by trying to pass various query strings.

Here's the code:

  file:processing_with_apache_args.pl
  -----------------------------------
  use strict;
  my $r = shift;
  $r->send_http_header('text/plain');
  my %args = $r->args;
  print join "\n", map {"$_ => ".$args{$_} } keys %args;

  file:processing_with_apache_request.pl
  --------------------------------------
  use strict;
  use Apache::Request ();
  my $r = shift;
  my $q = Apache::Request->new($r);
  $r->send_http_header('text/plain');
  my %args = map {$_ => $q->param($_) } $q->param;
  print join "\n", map {"$_ => ".$args{$_} } keys %args;

  file:processing_with_cgi_pm.pl
  ------------------------------
  use strict;
  use CGI;
  my $r = shift;
  $r->send_http_header('text/plain');
  my $q = new CGI;
  my %args = map {$_ => $q->param($_) } $q->param;
  print join "\n", map {"$_ => ".$args{$_} } keys %args;

All three scripts are preloaded at server startup:

  <Perl>
      use Apache::RegistryLoader ();
      Apache::RegistryLoader->new->handler(
                                "/perl/processing_with_cgi_pm.pl",
                     "/home/httpd/perl/processing_with_cgi_pm.pl"
                        );
      Apache::RegistryLoader->new->handler(
                                "/perl/processing_with_apache_request.pl",
                     "/home/httpd/perl/processing_with_apache_request.pl"
                        );
      Apache::RegistryLoader->new->handler(
                                "/perl/processing_with_apache_args.pl",
                     "/home/httpd/perl/processing_with_apache_args.pl"
                        );
  </Perl>

We use four different query strings, generated by:

  my @queries = (
      join("&", map {"$_=" . 'e' x 10}  ('a'..'b')),
      join("&", map {"$_=" . 'e' x 50}  ('a'..'b')),
      join("&", map {"$_=" . 'e' x 5 }  ('a'..'z')),
      join("&", map {"$_=" . 'e' x 10}  ('a'..'z')),
  );

The first string is:

  a=eeeeeeeeee&b=eeeeeeeeee

which is 25 characters in length and consists of two key/value pairs. The second string is also made of two key/value pairs, but the value is 50 characters long (total 105 characters). The third and the forth strings are made from 26 key/value pairs, with the value lengths of 5 and 10 characters respectively, with total lengths of 207 and 337 characters respectively. The query_len column in the report table is one of these four total lengths.

We conduct the benchmark with concurrency level of 50 and generate 5000 requests for each test.

And the results are:

  ---------------------------------------------
  name   val_len pairs query_len |  avtime  rps
  ---------------------------------------------
  apreq     10      2       25   |    51    945
  apreq     50      2      105   |    53    907
  r_args    50      2      105   |    53    906
  r_args    10      2       25   |    53    899
  apreq      5     26      207   |    64    754
  apreq     10     26      337   |    65    742
  r_args     5     26      207   |    73    665
  r_args    10     26      337   |    74    657
  cgi_pm    50      2      105   |    85    573
  cgi_pm    10      2       25   |    87    559
  cgi_pm     5     26      207   |   188    263
  cgi_pm    10     26      337   |   188    262
  ---------------------------------------------

Where apreq stands for Apache::Request::param(), r_args stands for Apache::args() or $r->args() and cgi_pm stands for CGI::param().

You can see that Apache::Request::param and Apache::args have similar performance with a few key/value pairs, but the former is faster with many key/value pairs. CGI::param is significantly slower than the other two methods.



TOP

Using $|=1 Under mod_perl and Better print() Techniques.

As you know, local $|=1; disables the buffering of the currently selected file handle (default is STDOUT). If you enable it, ap_rflush() is called after each print(), unbuffering Apache's IO.

If you are using multiple print() calls (_bad_ style in generating output) or if you just have too many of them, then you will experience a degradation in performance. The severity depends on the number of print() calls that you make.

Many old CGI scripts were written like this:

  print "<BODY BGCOLOR=\"black\" TEXT=\"white\">";
  print "<H1>";
  print "Hello";
  print "</H1>";
  print "<A HREF=\"foo.html\"> foo </A>";
  print "</BODY>";

This example has multiple print() calls, which will cause performance degradation with $|=1. It also uses too many backslashes. This makes the code less readable, and it is also more difficult to format the HTML so that it is easily readable as the script's output. The code below solves the problems:

  print qq{
    <BODY BGCOLOR="black" TEXT="white">
      <H1>
        Hello
      </H1>
      <A HREF="foo.html"> foo </A>
    </BODY>
  };

I guess you see the difference. Be careful though, when printing a <HTML> tag. The correct way is:

  print qq{<HTML>
    <HEAD></HEAD>
    <BODY>
  }

If you try the following:

  print qq{
    <HTML>
    <HEAD></HEAD>
    <BODY>
  }

Some older browsers expect the first characters after the headers and empty line to be <HTML> with no spaces before the opening left angle-bracket. If there are any other characters, they might not accept the output as HTML and print it as a plain text. Even if it works with your browser, it might not work for others.

One other approach is to use `here' documents, e.g.:

    print <<EOT;
    <HTML>
    <HEAD></HEAD>
    <BODY>
    EOT

Now let's go back to the $|=1 topic. I still disable buffering, for two reasons:

An even better solution is to keep buffering enabled, and use a Perl API rflush() call to flush the buffers when needed. This way you can place the first part of the page that you are going to send to the user in the buffer, and flush it a moment before you are going to do some lengthy operation, like a DB query. So you kill two birds with one stone: you show some of the data to the user immediately, so she will feel that something is actually happening, and you have no performance hit from disabled buffering.

  use CGI ();
  my $r = shift;
  my $q = new CGI;
  print $q->header('text/html');
  print $q->start_html;
  print $q->p("Searching...Please wait");
  $r->rflush;
    # imitate a lengthy operation
  for (1..5) {
    sleep 1;
  }
  print $q->p("Done!");

Conclusion: Do not blindly follow suggestions, but think what is best for you in each case.

Note: It might happen that some browsers do not render the page before they have received a significant amount. This is especially true if you insert <link< or <script> tags in your HTML header that require the browser to load a separate file. In that case, the user won't be able to see the content at once, no matter if you flush the buffers or not.

A workaround for this might be to use an output filter that replaces these tags with the files they refer to.



TOP

Global vs. Fully Qualified Variables

It's always a good idea to avoid using global variables where it's possible. Some variables must be either global, such as @ISA or else fully qualified such as @MyModule::ISA, so that Perl can see them from different packages.

A combination of strict and vars pragmas keeps modules clean and reduces a bit of noise. However, the vars pragma also creates aliases, as does Exporter, which eat up more memory. When possible, try to use fully qualified names instead of use vars.

For example write:

  package MyPackage1;
  use strict;
  use vars; # added only for fair comparison
  @MyPackage1::ISA = qw(CGI);
  $MyPackage1::VERSION = "1.00";
  1;

instead of:

  package MyPackage2;
  use strict;
  use vars qw(@ISA $VERSION);
  @ISA = qw(CGI);
  $VERSION = "1.00";
  1;

Note that we have added the vars pragma in the package that doesn't use it so the memory comparison will be fair.

Here are the numbers under Perl version 5.6.0

  % perl -MGTop -MMyPackage1 -le 'print GTop->new->proc_mem($$)->size'
    2023424
  % perl -MGTop -MMyPackage2 -le 'print GTop->new->proc_mem($$)->size'
    2031616

We have a difference of 8192 bytes. So every few global variables declared with vars pragma add about 8KB overhead.

Note that Perl 5.6.0 introduced a new our() pragma which works like my () scope-wise, but declares global variables.

  package MyPackage3;
  use strict;
  use vars; # not needed, added only for fair comparison
  our @ISA = qw(CGI);
  our $VERSION = "1.00";
  1;

which uses the same amount of memory as a fully qualified global variable:

  % perl -MGTop -MMyPackage3 -le 'print GTop->new->proc_mem($$)->size'
  2023424

Imported symbols act just like global variables, they can add up quick:

  % perlbloat.pl 'use POSIX ()'
  use POSIX () added  316k

  % perlbloat.pl 'use POSIX'
  use POSIX added  696k

That's 380k worth of aliases. Now let's say 6 different Apache::Registry scripts 'use POSIX;' for strftime() or some other function: 6 * 380k = 2.3Mb

One could save 2.3Mb per single process with 'use POSIX ();' and using fully qualifying POSIX:: function calls.



TOP

Object Methods Calls vs. Function Calls

Which subroutine calling form is more efficient: Object methods or functions?



TOP

The Overhead with Light Subroutines

Let's do some benchmarking. We will start doing it using empty methods, which will allow us to measure the real difference in the overhead each kind of call introduces. We will use this code:

  bench_call1.pl
  --------------
  package Foo;
  
  use strict;
  use Benchmark;
  
  sub bar { };
  
  timethese(50_000, {
                 method   => sub { Foo->bar()      },
                 function => sub { Foo::bar('Foo');},
                });

The two calls are equivalent, since both pass the class name as their first parameter; function does this explicitly, while method does this transparently.

The benchmarking result:

  Benchmark: timing 50000 iterations of function, method...
    function:  0 wallclock secs ( 0.80 usr +  0.05 sys =  0.85 CPU)
      method:  1 wallclock secs ( 1.51 usr +  0.08 sys =  1.59 CPU)

We are interested in the 'total CPU times' and not the 'wallclock seconds'. It's possible that the load on the system was different for the two tests while benchmarking, so the wallclock times give us no useful information.

We see that the method calling type is almost twice as slow as the function call, 0.85 CPU compared to 1.59 CPU real execution time. Why does this happen? Because the difference between functions and methods is the time taken to resolve the pointer from the object, to find the module it belongs to and then the actual method. The function form has one parameter less to pass, less stack operations, less time to get to the guts of the subroutine.

perl5.6+ does better method caching, Foo->method() is a little bit faster (some constant folding magic), but not Foo->$method(). And the improvement does not address the @ISA lookup that still happens in either case.



TOP

The Overhead with Heavy Subroutines

But that doesn't mean that you shouldn't use methods. Generally your functions do something, and the more they do the less significant is the time to perform the call, because the calling time is effectively fixed and is probably a very small overhead in comparison to the execution time of the method or function itself. Therefore the longer execution time of the function the smaller the relative overhead of the method call. The next benchmark proves this point:

  bench_call2.pl
  --------------
  package Foo;
  
  use strict;
  use Benchmark;
  
  sub bar { 
    my $class = shift;
  
    my ($x,$y) = (100,100);
    $y = log ($x ** 10)  for (0..20);
  };
  
  timethese(50_000, {
                 method   => sub { Foo->bar()      },
                 function => sub { Foo::bar('Foo');},
                });

We get a very close benchmarks!

  function: 33 wallclock secs (15.81 usr +  1.12 sys = 16.93 CPU)
    method: 32 wallclock secs (18.02 usr +  1.34 sys = 19.36 CPU)

Let's make the subroutine bar even slower:

  sub bar { 
    my $class = shift;
  
    my ($x,$y) = (100,100);
    $y = log ($x ** 10)  for (0..40);
  };

And the result is amazing, the method call convention was faster than function:

  function: 81 wallclock secs (25.63 usr +  1.84 sys = 27.47 CPU)
    method: 61 wallclock secs (19.69 usr +  1.49 sys = 21.18 CPU)

In case your functions do very little, like the functions that generate HTML tags in CGI.pm, the overhead might become a significant one. If your goal is speed you might consider using the function form, but if you write a big and complicated application, it's much better to use the method form, as it will make your code easier to develop, maintain and debug, saving programmer time which, over the life of a project may turn out to be the most significant cost factor.



TOP

Are All Methods Slower than Functions?

Some modules' API is misleading, for example CGI.pm allows you to execute its subroutines as functions or as methods. As you will see in a moment its function form of the calls is slower than the method form because it does some voodoo work when the function form call is used.

  use CGI;
  my $q = new CGI;
  $q->param('x',5);
  my $x = $q->param('x');

vs

  use CGI qw(:standard);
  param('x',5);
  my $x = param('x');

As usual, let's benchmark some very light calls and compare. Ideally we would expect the methods to be slower than functions based on the previous benchmarks:

  bench_call3.pl
  ---------------
  use Benchmark;
  
  use CGI qw(:standard);
  $CGI::NO_DEBUG = 1;
  my $q = new CGI;
  my $x;
  timethese
    (20000, {
      method   => sub {$q->param('x',5); $x = $q->param('x'); },
      function => sub {    param('x',5); $x =     param('x'); },
     });

The benchmark is written is such a way that all the initializations are done at the beginning, so that we get as accurate performance figures as possible. Let's do it:

  % ./bench_call3.pl
  
  function: 51 wallclock secs (28.16 usr +  2.58 sys = 30.74 CPU)
    method: 39 wallclock secs (21.88 usr +  1.74 sys = 23.62 CPU)

As we can see methods are faster than functions, which seems to be wrong. The explanation lays in the way CGI.pm is implemented. CGI.pm uses some fancy tricks to make the same routine act both as a method and a plain function. The overhead of checking whether the arguments list looks like a method invocation or not, will mask the slight difference in time for the way the function was called.

If you are intrigued and want to investigate further by yourself the subroutine you want to explore is called self_or_default. The first line of this function short-circuits if you are using the object methods, but the whole function is called if you are using the functional forms. Therefore, the functional form should be slightly slower than the object form.



TOP

Imported Symbols and Memory Usage

There is a real memory hit when you import all of the functions into your process' memory. This can significantly enlarge memory requirements, particularly when there are many child processes.

In addition to polluting the namespace, when a process imports symbols from any module or any script it grows by the size of the space allocated for those symbols. The more you import (e.g. qw(:standard) vs qw(:all)) the more memory will be used. Let's say the overhead is of size X. Now take the number of scripts in which you deploy the function method interface, let's call that Y. Finally let's say that you have a number of processes equal to Z.

You will need X*Y*Z size of additional memory, taking X=10k, Y=10, Z=30, we get 10k*10*30 = 3Mb!!! Now you understand the difference.

Let's benchmark CGI.pm using GTop.pm. First we will try it with no exporting at all.

  use GTop ();
  use CGI ();
  print GTop->new->proc_mem($$)->size;

  1,949,696

Now exporting a few dozens symbols:

  use GTop ();
  use CGI qw(:standard);
  print GTop->new->proc_mem($$)->size;

  1,966,080

And finally exporting all the symbols (about 130)

  use GTop ();
  use CGI qw(:all);
  print GTop->new->proc_mem($$)->size;

  1,970,176

Results:

  import symbols  size(bytes)  delta(bytes) relative to ()
  --------------------------------------
  ()              1949696             0
  qw(:standard)   1966080         16384
  qw(:all)        1970176         20480

So in my example above X=20k => 20K*10*30 = 6Mb. You will need 6Mb more when importing all the CGI.pm's symbols than when you import none at all.

Generally you use more than one script, run more than one process and probably import more symbols from the additional modules that you deploy. So the real numbers are much bigger.

The function method is faster in the general case, because of the time overhead to resolve the pointer from the object.

If you are looking for performance improvements, you will have to face the fact that having to type My::Module::my_method might save you a good chunk of memory if the above call must not be called with a reference to an object, but even then it can be passed by value.

I strongly endorse Apache::Request (libapreq) - Generic Apache Request Library. Its core is written in C, giving it a significant memory and performance benefit. It has all the functionality of CGI.pm except the HTML generation functions.



TOP

Interpolation, Concatenation or List

Somewhat overlapping with the previous section we want to revisit the various approaches of mungling with strings, and compare the speed of using lists of strings compared to interpolation. We will add a string concatenation angle as well.

When the strings are small, it almost doesn't matter whether interpolation or a list is used. Here is a benchmark:

  use Benchmark;
  use Symbol;
  my $fh = gensym;
  open $fh, ">/dev/null" or die;
    
  my ($one, $two, $three, $four) = ('a'..'d');
  
  timethese(1_000_000,
      {
       interp => sub {
         print $fh "$one$two$three$four";
       },
       list => sub {
         print $fh $one, $two, $three, $four;
       },
       conc => sub {
         print $fh $one.$two.$three.$four;
       },
      });

 Benchmark: timing 1000000 iterations of conc, interp, list...
      conc:  3 wallclock secs ( 3.38 usr +  0.00 sys =  3.38 CPU)
    interp:  3 wallclock secs ( 3.45 usr + -0.01 sys =  3.44 CPU)
      list:  2 wallclock secs ( 2.58 usr +  0.00 sys =  2.58 CPU)

The concatenation technique is very similar to interpolation. The list technique is a little bit faster than interpolation. But when the strings are large, lists are significantly faster. We have seen this in the previous section and here is another benchmark to increase our confidence in our conclusion. This time we use 1000 character long strings:

  use Benchmark;
  use Symbol;
  my $fh = gensym;
  open $fh, ">/dev/null" or die;
  
  my ($one, $two, $three, $four) = map { $_ x 1000 } ('a'..'d');
  
  timethese(500_000,
      {
       interp => sub {
         print $fh "$one$two$three$four";
       },
       list => sub {
         print $fh $one, $two, $three, $four;
       },
       conc => sub {
         print $fh $one.$two.$three.$four;
       },
      });

  Benchmark: timing 500000 iterations of interp, list...
      conc:  5 wallclock secs ( 4.47 usr +  0.27 sys =  4.74 CPU)
    interp:  4 wallclock secs ( 4.25 usr +  0.26 sys =  4.51 CPU)
      list:  4 wallclock secs ( 2.87 usr +  0.16 sys =  3.03 CPU)

In this case using a list is about 30% faster than interpolation. Concatenation is a little bit slower than interpolation.

Let's look at this code:

    $title = 'My Web Page';
    print "<h1>$title</h1>";         # Interpolation (slow)
    print '<h1>' . $title . '</h1>'; # Concatenation (slow)
    print '<h1>', $title, '</h1>';   # List (fast for long strings)

When you use "<h1>$title</h1>" Perl does interpolation (since "" is an operator in Perl), which must parse the contents of the string and replace any variables or expressions it finds with their respective values. This uses more memory and is slower than using a list. Of course if there are no variables to interpolate it makes no difference whether to use "string" or 'string'.

Concatenation is also potentially slow since Perl might create a temporary string which it then prints.

Lists are fast because Perl can simply deal with each element in turn. This is true if you don't run join() on the list at the end to create a single string from the elements of list. This operation might be slower than direct append to the string whenever a new string springs into existence.

[ReaderMETA]: Please send more mod_perl relevant Perl performance hints



TOP

Using Perl stat() Call's Cached Results

When you do a stat() (or its variations -M -- last modification time, -A -- last access time, -C -- last inode-change time, etc), the returned information is cached internally. If you need to make an additional check for the same file, use the _ magic variable and save the overhead of an unnecessary stat() call. For example when testing for existence and read permissions you might use:

  my $filename = "./test";
    # three stat() calls
  print "OK\n" if -e $filename and -r $filename;
  my $mod_time = (-M $filename) * 24 * 60 * 60;
  print "$filename was modified $mod_time seconds before startup\n";

or the more efficient:

  my $filename = "./test";
    # one stat() call
  print "OK\n" if -e $filename and -r _;
  my $mod_time = (-M _) * 24 * 60 * 60;
  print "$filename was modified $mod_time seconds before startup\n";

Two stat() calls were saved!



TOP

Optimizing Code

Here are some other resources that explain how to optimize your code, which are usually applied when you profile your code and need to optimize it but in many cases are useful to know when you develop the code.

[ReaderMETA]: please send me similar resources if you know of such.



TOP

Apache::Registry and Derivatives Specific Notes

These are the sections that deal solely with Apache::Registry and derived modules, like Apache::PerlRun and Apache::RegistryBB. No Perl handlers code is discussed here, so if you don't use these modules, feel free to skip this section.



TOP

Be Careful with Symbolic Links

As you know Apache::Registry caches the scripts in the packages whose names are constructed by scripts' URI. If you have the same script that can be reached by different URIs, which is possible if you have used symbolic links, you will get the same script stored twice in the memory.

For example:

  % ln -s /home/httpd/perl/news/news.pl /home/httpd/perl/news.pl

Now the script can be reached through the both URIs /news/news.pl and /news.pl. It doesn't really matter until you advertise the two URIs, and users reach the same script from both of them.

So let's assume that you have issued the requests to the both URIs:

  http://localhost/perl/news/news.pl
  http://localhost/perl/news.pl

To spot the duplication you should use the Apache::Status module. Amongst other things, it shows all the compiled Apache::Registry scripts (using their respective packages):

If you are using the default configuration directives you should either use this URI:

  http://localhost/perl-status?rgysubs

or just go to the main menu at:

  http://localhost/perl-status

And click on Compiled Registry Scripts menu item.

META: we need a screen snapshot here!!!

If you the script was accessed through the URI that was remapped to the real file and through the URI that was remapped to the symbolic link, you will see the following output:

  Apache::ROOT::perl::news::news_2epl
  Apache::ROOT::perl::news_2epl

You should run the server in the single mode, to see it immediately. If you test it in the normal mode--it's possible that some child processes would show only one entry or none at all, since they might not serve the same requests as the others. For more hints see the section "Run the server in single mode".



TOP

Improving Performance by Prevention

There are two ways to improve performance: one is by tuning to squeeze the most out of your hardware and software; and the other is preventing certain bad things from happening, like impolite robots that crawl your site without pausing between requests, memory leakages, getting the memory unshared, making sure that some processes won't take up all the CPU etc.

In the following sections we are going to discuss about the tools and programming techniques that would help you to keep your service in order, even if you are not around.



TOP

Memory leakage

Scripts under mod_perl can very easily leak memory! Global variables stay around indefinitely, lexically scoped variables (declared with my ()) are destroyed when they go out of scope, provided there are no references to them from outside that scope.

Perl doesn't return the memory it acquired from the kernel. It does reuse it though!



TOP

Reading In A Whole File

  open IN, $file or die $!;
  local $/ = undef; # will read the whole file in
  $content = <IN>;
  close IN;

If your file is 5Mb, the child which served that script will grow by exactly that size. Now if you have 20 children, and all of them will serve this CGI, they will consume 20*5M = 100M of RAM in total! If that's the case, try to use other approaches to processing the file, if possible. Try to process a line at a time and print it back to the file. If you need to modify the file itself, use a temporary file. When finished, overwrite the source file. Make sure you use a locking mechanism!



TOP

Copying Variables Between Functions

Now let's talk about passing variables by value. Let's use the example above, assuming we have no choice but to read the whole file before any data processing takes place. Now you have some imaginary process() subroutine that processes the data and returns it. What happens if you pass the $content by value? You have just copied another 5M and the child has grown in size by another 5M. Watch your swap space! Now multiply it again by factor of 20 you have 200M of wasted RAM, which will apparently be reused, but it's a waste! Whenever you think the variable can grow bigger than a few Kb, pass it by reference!

Once I wrote a script that passed the contents of a little flat file database to a function that processed it by value -- it worked and it was fast, but after a time the database became bigger, so passing it by value was expensive. I had to make the decision whether to buy more memory or to rewrite the code. It's obvious that adding more memory will be merely a temporary solution. So it's better to plan ahead and pass variables by reference, if a variable you are going to pass might eventually become bigger than you envisage at the time you code the program. There are a few approaches you can use to pass and use variables passed by reference. For example:

  my $content = qq{foobarfoobar};
  process(\$content);
  sub process{
    my $r_var = shift; 
    $$r_var =~ s/foo/bar/gs;
      # nothing returned - the variable $content outside has already 
      # been modified
  }

If you work with arrays or hashes it's:

  @{$var_lr}  dereferences an array
  %{$var_hr}  dereferences a hash

We can still access individual elements of arrays and hashes that we have a reference to without dereferencing them:

  $var_lr->[$index]  get $index'th element of an array via a ref
  $var_hr->{$key}    get $key'th element of a hash via a ref

For more information see perldoc perlref.

Another approach would be to use the @_ array directly. This has the effect of passing by reference:

  process($content);
  sub process{
    $_[0] =~ s/foo/bar/gs;
      # nothing returned - the variable $content outside has been
      # already modified
  }

From perldoc perlsub:

      The array @_ is a local array, but its elements are aliases for
      the actual scalar parameters.  In particular, if an element
      $_[0] is updated, the corresponding argument is updated (or an
      error occurs if it is not possible to update)...

Be careful when you write this kind of subroutine, since it can confuse a potential user. It's not obvious that call like process($content); modifies the passed variable. Programmers (the users of your library in this case) are used to subroutines that either modify variables passed by reference or expressly return a result (e.g. $content=process($content);).



TOP

Work With Databases

If you do some DB processing, you will often encounter the need to read lots of records into your program, and then print them to the browser after they are formatted. I won't even mention the horrible case where programmers read in the whole DB and then use Perl to process it!!! Use a relational DB and let the SQL do the job, so you get only the records you need!

We will use DBI for this (assume that we are already connected to the DB--refer to perldoc DBI for a complete reference to the DBI module):

  $sth->execute;
  while(@row_ary  = $sth->fetchrow_array) {
    # do DB accumulation into some variable
  }
  # print the output using the data returned from the DB

In the example above the httpd_process will grow by the size of the variables that have been allocated for the records that matched the query. Again remember to multiply it by the number of the children your server runs!

A better approach is not to accumulate the records, but rather to print them as they are fetched from the DB. Moreover, we will use the bind_col() and $sth->fetchrow_arrayref() (aliased to $sth->fetch()) methods, to fetch the data in the fastest possible way. The example below prints an HTML table with matched data, the only memory that is being used is a @cols array to hold temporary row values. The table will be rendered by the client browser only when the whole table will be out though.

  my @select_fields = qw(a b c);
      # create a list of cols values
  my @cols = ();
  @cols[0..$#select_fields] = ();
  $sth = $dbh->prepare($do_sql);
  $sth->execute;
    # Bind perl variables to columns.
  $sth->bind_columns(undef,\(@cols));
  print "<TABLE>";
  while($sth->fetch) {
     print "<TR>",
           map("<TD>$_</TD>", @cols),
           "</TR>";
  }
  print "</TABLE>";

Note: the above method doesn't allow you to know how many records have been matched. The workaround is to run an identical query before the code above where you use SELECT count(*) ... instead of 'SELECT * ..., to get the number of matched records. It should be much faster, since you can remove any SORTBY and similar attributes.

For those who think that $sth->rows will do the job, here is the quote from the DBI manpage:

  rows();

  $rv = $sth->rows;

  Returns the number of rows affected by the last database altering
  command, or -1 if not known or not available.  Generally you can
  only rely on a row count after a do or non-select execute (for some
  specific operations like update and delete) or after fetching all
  the rows of a select statement.

  For select statements it is generally not possible to know how many
  rows will be returned except by fetching them all.  Some drivers
  will return the number of rows the application has fetched so far
  but others may return -1 until all rows have been fetched. So use of
  the rows method with select statements is not recommended.

As a bonus, I wanted to write a single sub that flexibly processes any query. It would accept conditions, a call-back closure sub, select fields and restrictions.

  # Usage:
  # $o->dump(\%conditions,\&callback_closure,\@select_fields,@restrictions);
  #
  sub dump{
    my $self = shift;
    my %param = %{+shift}; # dereference hash
    my $rsub = shift;
    my @select_fields = @{+shift}; # dereference list
    my @restrict = shift || '';
  
      # create a list of cols values
    my @cols = ();
    @cols[0..$#select_fields] = ();
  
    my $do_sql = '';
    my @where = ();
  
      # make a @where list 
    map { push @where, "$_=\'$param{$_}\'" if $param{$_};} keys %param;
  
      # prepare the sql statement
    $do_sql = "SELECT ";
    $do_sql .= join(" ", @restrict) if @restrict;    # append restriction list
    $do_sql .= " " .join(",", @select_fields) ;      # append select list 
    $do_sql .= " FROM $DBConfig{TABLE} ";            # from table
  
      # we will not add the WHERE clause if @where is empty
    $do_sql .= " WHERE " . join " AND ", @where if @where;
  
    print "SQL: $do_sql \n" if $debug;
  
    $dbh->{RaiseError} = 1; # do this, or check every call for errors
    $sth = $dbh->prepare($do_sql);
    $sth->execute;
      # Bind perl variables to columns.
    $sth->bind_columns(undef,\(@cols));
    while($sth->fetch) {
      &$rsub(@cols);
    }
      # print the tail or "no records found" message
      # according to the previous calls
    &$rsub();
  
  } # end of sub dump

Now a callback closure sub can do lots of things. We need a closure to know what stage are we in: header, body or tail. For example, we want a callback closure for formatting the rows to print:

  my $rsub = eval {
      # make a copy of @fields list, since it might go
      # out of scope when this closure is called
    my @fields = @fields; 
    my @query_fields = qw(user dir tool act);   # no date field!!!
    my $header = 0;
    my $tail   = 0;
    my $counter = 0;
    my %cols = ();                     # columns name=> value hash
  
    # Closure with the following behavior:
    # 1. Header's code will be executed on the first call only and
    #    if @_ was set
    # 2. Row's printing code will be executed on every call with @_ set
    # 3. Tail's code will be executed only if Header's code was
    #    printed and @_ isn't set
    # 4. "No record found" code will be executed if Header's code
    #    wasn't executed
  
    sub {
          # Header
    if (@_ and !$header){
      print "<TABLE>\n";
      print $q->Tr(map{ $q->td($_) } @fields );
      $header = 1; 
    }
    
      # Body
    if (@_) {
      print $q->Tr(map{$q->td($_)} @_ );
      $counter++;
      return; 
    }
    
          # Tail, will be printed only at the end
    if ($header and !($tail or @_)){
      print "</TABLE>\n $counter records found";
      $tail = 1;
      return;
    }
    
          # No record found
    unless ($header){
      print $q->p($q->center($q->b("No record was found!\n")));
    }
  
      }  #  end of sub {}
  };  #  end of my $rsub = eval {

You might also want to check the section Preventing Your Processes from Growing and Limiting Other Resources Used by Apache Child Processes.



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Avoid the Evil Troika

The perlre manpage says:

  WARNING: Once Perl sees that you need one of "$&", "$`", or "$'"
  anywhere in the program, it has to provide them for every pattern
  match. This may substantially slow your program.

The mere existence of these variables will trigger this behavior, regardless of whether or not the code that accesses them will be executed. Removing these variables should significantly improve the regex performance.

How do you know whether some code loads them? You could grep(1), but it's hard to remember to do that as you include more modules from CPAN and write new code. Luckily Devel::SawAmpersand comes to help. (http://search.cpan.org/dist/Devel-SawAmpersand/lib/Devel/SawAmpersand.pm) This module will alert you if it detects any of the evil troika variables present.



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Preventing Your Processes from Growing

If you have already worked with mod_perl, you have probably noticed that it can be difficult to keep your mod_perl processes from using a lot of memory. The less memory you have, the fewer processes you can run and the worse your server will perform, especially under a heavy load. This chapter presents several common situations which can lead to unnecessary consumption of RAM, together with preventive measures.

When you need to control the size of your httpd processes, use one of the two modules Apache::GTopLimit and Apache::SizeLimit which kill Apache httpd processes when the latter grow too large or lose a big chunk of their shared memory. The two modules differ in methods for finding out the memory usage. Apache::GTopLimit relies on the libgtop library to perform this task, therefore if this library can be built on your platform you can use this module. Apache::SizeLimit includes different methods for different platforms, you will have to check the modules' manpage to figure out which platforms are supported.



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Defining the Minimum Shared Memory Size Threshold

As we have already discussed, when it is first created an Apache child process usually has a large fraction of it memory shared with its parent. During the child process' life some of its data structures are modified and a part of its memory becomes unshared (pages become "dirty"), leading to an increase in memory consumption. You will remember that the MaxRequestsPerChild directive allows you to specify the number of requests a child process should serve before it is killed. One way to limit the memory consumption of a process is to kill it and let Apache replace it with a newly started process, which again will have all its memory shared with the Apache parent. The new child process serves requests and eventually the cycle is repeated.

This is a fairly crude means of limiting unshared memory and you will probably need to tune MaxRequestsPerChild, eventually finding an optimum value. If, as is likely, your service is undergoing constant changes then this is an inconvenient solution. You have to re-tune this number again and again to adapt to the ever changing code base.

You really want to set some guardian to watch the shared size and kill the process if it goes below some limit. This way, processes will not be killed unnecessarily.

To set a shared memory lower limit of 4MB using Apache::GTopLimit add the following code into the startup.pl file:

  use Apache::GTopLimit;
  $Apache::GTopLimit::MIN_PROCESS_SHARED_SIZE = 4096;

and in httpd.conf:

  PerlFixupHandler Apache::GTopLimit

don't forget to restart the server for the changes to take effect.

This has the effect that as soon as the child process shares less than 4MB, (the corollary being that it must therefore be occupying a lot of memory with its unique pages), it will be killed after completing to serve the last request, and, as a consequence, a new child will take its place.

If you use Apache::SizeLimit you can accomplish the same with the adding to startup.pl:

  use Apache::SizeLimit;
  $Apache::SizeLimit::MIN_SHARE_SIZE = 4096;

and in httpd.conf:

  PerlFixupHandler Apache::SizeLimit

If you only want to set this limit for some requests (presumably the ones which you think are likely to cause memory to become unshared) then you can register a post-processing check using the set_min_shared_size() function. For example:

    use Apache::GTopLimit;
    if ($need_to_limit) {
        # make sure that at least 4MB are shared
        Apache::GTopLimit->set_min_shared_size(4096);
    }

or for Apache::SizeLimit:

    use Apache::SizeLimit;
    if ($need_to_limit) {
        # make sure that at least 4MB are shared
        Apache::SizeLimit->setmin(4096);
    }

Since accessing the process information adds a little overhead, you may want to only check the process size every N times. In this case set the $Apache::GTopLimit::CHECK_EVERY_N_REQUESTS variable. For example to test the size every other time, put in your startup.pl:

  $Apache::GTopLimit::CHECK_EVERY_N_REQUESTS = 2;

or for Apache::SizeLimit:

  $Apache::SizeLimit::CHECK_EVERY_N_REQUESTS = 2;

You can run the Apache::GTopLimit module in the debug mode by setting:

    PerlSetVar Apache::GTopLimit::DEBUG 1

in httpd.conf. It's important that this setting should happen before the Apache::GTopLimit module is loaded.

When debug mode is turned on the module reports in the error_log file the memory usage of the current process and also when it detects that at least one of the thresholds was crosses and the process is going to be killed.

Apache::SizeLimit controls the debug level via $Apache::SizeLimit::DEBUG variable:

  $Apache::SizeLimit::DEBUG = 1;

which can be modified any time, even after the module was loaded.



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Potential Drawbacks of Memory Sharing Restriction

It's very important that the system won't be heavily engaged in swapping process. Some systems do swap in and out every so often even if they have plenty of real memory available and it's OK. The following applies to conditions when there is hardly any free memory available.

So if the system uses almost all of its real memory (including the cache), there is a danger of parent's process memory pages being swapped out (written to a swap device). If this happens the memory usage reporting tools will report all those swapped out pages as non-shared, even though in reality these pages are still shared on most OSs. When these pages are getting swapped in, the sharing will be reported back to normal after a certain amount of time. If a big chunk of the memory shared with child processes is swapped out, it's most likely that Apache::SizeLimit or Apache::GTopLimit will notice that the shared memory floor threshold was crossed and as a result kill those processes. If many of the parent process' pages are swapped out, and the newly created child process is already starting with shared memory below the limit, it'll be killed immediately after serving a single request (assuming that we the $CHECK_EVERY_N_REQUESTS is set to one). This is a very bad situation which will eventually lead to a state where the system won't respond at all, as it'll be heavily engaged in swapping process.

This effect may be less or more severe depending on the memory manager's implementation and it certainly varies from OS to OS, and different kernel versions. Therefore you should be aware of this potential problem and simply try to avoid situations where the system needs to swap at all, by adding more memory, reducing the number of child servers or spreading the load across more machines, if reducing the number of child servers is not an options because of the request rate demands.



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Defining the Maximum Memory Size Threshold

Not less important than maximizing shared memory is restricting the absolute size of the processes. If the processes grow after each request, and if nothing restricts them from growing, you can easily run out of memory.

Again you can set the MaxRequestPerChild directive to kill the processes after a few requests have been served. But as we have explained in the previous section this solution is not as good as one which monitors the process size and kills it only when some limit is reached.

If you have Apache::GTopLimit (described in the previous section) you can limit process' memory usage by setting the $Apache::GTopLimit::MAX_PROCESS_SIZE directive. For example if you want the processes to be killed when they reach 10MB you should put the following in your startup.pl file:

    $Apache::GTopLimit::MAX_PROCESS_SIZE = 10240;

Just as when limiting shared memory, you can set a limit for the current process using the set_max_size() method in your code:

    use Apache::GTopLimit;
    Apache::GTopLimit->set_max_size(10000);

For Apache::SizeLimit the equivalents are:

  use Apache::SizeLimit;
  $Apache::SizeLimit::MAX_PROCESS_SIZE = 10240;

and:

  use Apache::SizeLimit;
  Apache::SizeLimit->setmax(10240);


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Defining the Maximum Unshared Memory Size Threshold

Instead of setting the shared and total memory usage thresholds, you can set a single threshold which measures the amount of unshared memory, by subtracting the shared memory size from the total memory size.

Both modules allow you to set the thresholds in similar ways. With Apache::GTopLimit you can set the unshared memory threshold server-wide with:

  $Apache::GTopLimit::MAX_PROCESS_UNSHARED_SIZE = 6144;

and locally for a handler with:

  Apache::GTopLimit->set_max_unshared_size(6144);

If you are using Apache::SizeLimit the corresponding settings would be:

  $Apache::SizeLimit::MAX_UNSHARED_SIZE = 6144;

and:

  Apache::SizeLimit->setmax_unshared(6144);


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Limiting Other Resources Used by Apache Child Processes

In addition to the absolute and shared memory sizes limiting, you might need to prevent the processes from excessive consumption of the system resources. Like limiting the CPU usage, the number of files that can be opened, or memory segment usage and more.

The Apache::Resource module allows this all by deploying the BSD::Resource module, which in turn uses the C function setrlimit() to set limits on system resources.

A resource limit is specified as a soft limit and a hard limit. When a soft limit is exceeded a process may receive a signal (for example, if the CPU time or file size is exceeded), but it will be allowed to continue execution until it reaches the hard limit (or modifies its resource limit). The rlimit structure is used to specify the hard and soft limits on a resource. (See the manpage for setrlimit for your OS specific information.)

If the value of the variable is of the form S:H, S is treated as the soft limit, and H is the hard limit. If it is just a single number, it is used for both soft and hard limits. So if you set 10:20, the soft limit is 10 and the hard limit is 20. If you set just 10--both the soft and the hard limits are set to 20.

The mostly spread usage of this module is to limit the CPU usage. The environment variable PERL_RLIMIT_CPU defines the maximum amount of CPU time the process can use. If it runs for longer than this, it gets killed, no matter what it does, either processing a new request or just waiting. This is very useful when you have a code with a bug and the process starts to spin in an infinite loop or alike using a lot of CPU and never completing the request.

The value is measured in seconds. The following example sets the soft limit of the CPU usage to 120 seconds (the default is 360).

  PerlModule Apache::Resource
  PerlSetEnv PERL_RLIMIT_CPU 120

Of course you should tell mod_perl to use this module, which is done by adding the following directive to httpd.conf:

  PerlChildInitHandler Apache::Resource

There are other resources that you might want to limit. For example you can limit the memory data and stack segment sizes (PERL_RLIMIT_DATA and PERL_RLIMIT_STACK), the maximum process file size (PERL_RLIMIT_FSIZE), the core file size (PERL_RLIMIT_CORE), the address space (virtual memory) limit (PERL_RLIMIT_AS), etc. Refer to the setrlimit(2) man page on your OS for other possible resources. Remember to prepend PERL_ before the resource types you will see in the man page.

If you configure Apache::Status, it will let you review the resources set in this way. Remember that Apache::Status must be loaded before Apache::Resource in order to enable the resources display menu.

If you want to set the debug mode set the $Apache::Resource::Debug before loading the module, for example by using the Perl sections in httpd.conf.

  <Perl>
    $Apache::Resource::Debug = 1;
    require Apache::Resource;
  </Perl>
  PerlChildInitHandler Apache::Resource

Now open in the error_log file using tell and watch the debug messages showing up, when the requests are served.



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OS Specific notes

Note that under Linux malloc() uses mmap() instead of brk(). This is done to conserve virtual memory - that is, when you malloc a large block of memory, it isn't actually given to your program until you initialize it. The old-style brk() system call obeyed resource limits on data segment size as set in setrlimit() - mmap() doesn't.

Apache::Resource's defaults put caps on data size and stack size. Linux's current memory allocation scheme doesn't honor these limits, so if you just do

  PerlSetEnv PERL_RLIMIT_DEFAULTS On
  PerlModule Apache::Resource
  PerlChildInitHandler Apache::Resource

Your Apache processes are still free to use as much memory as they like.

However, BSD::Resource also has a limit called RLIMIT_AS (Address Space) which limits the total number of bytes of virtual memory assigned to a process. Happily, Linux's memory manager does honor this limit.

Therefore, you can limit memory usage under Linux with Apache::Resource -- simply add a line to httpd.conf:

  PerlSetEnv PERL_RLIMIT_AS  67108864

This example sets a hard and soft limit of 64MB of total address space.

Refer to the Apache::Resource and setrlimit(2) manpages for more information.



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Limiting the Number of Processes Serving the Same Resource

If you want to limit number of Apache children that could simultaneously be serving the (nearly) same resource, you should take a look at the mod_throttle_access module.

It solves the problem of too many concurrent request accessing the same URI, if for example the handler that serves this URI uses some resource that has a limitation on the maximum number of possible users or the handlers code is very CPU intensive and you cannot afford more than a certain number of concurrent requests to this specific URI.

Imagine that your service provides the three following URIs:

  /perl/news/
  /perl/webmail/
  /perl/morphing/

The first two URIs are response critical as people want to read news and their email. The third URI is very CPU and RAM intensive image morphing service, provided as a bonus to your users. Since you don't want users to abuse this service, you have to set some limits on the number of concurrent requests for this resource, since if you don't--the other two critical resources can be hurt.

When you compile in and enable the Apache mod_throttle_access module, the MaxConcurrentReqs directive becomes available. For example, the following setting:

  <Location "/perl/morphing">
    <Limit PUT GET POST>
      MaxConcurrentReqs 10
    </Limit>
  </Location>

will allow only 10 concurrent PUT, GET or POST requests under the URI /perl/morphing to be processed at one time. The other two URIs remain unlimited.



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Limiting the Request Rate Speed (Robot Blocking)

A limitation of using pattern matching to identify robots is that it only catches the robots that you know about, and then only those that identify themselves by name. A few devious robots masquerade as users by using user agent strings that identify themselves as conventional browsers. To catch such robots, you'll have to be more sophisticated.

Apache::SpeedLimit comes to your aid, see:

http://www.modperl.com/chapters/ch6.html#Blocking_Greedy_Clients



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Perl Modules for Performance Improvement

These sections are about Perl modules that improve performance without requiring changes to your code. Mostly you just need to tweak the configuration file to plug these modules in.



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Sending Plain HTML as Compressed Output

See Apache::GzipChain - compress HTML (or anything) in the OutputChain



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Caching Components with HTML::Mason

META: complete the full description

HTML::Mason is a system that makes use of components to build HTML pages.

If most of your output is generated dynamically, but each finished page can be separated into different components, HTML::Mason can cache those components. This can really improve the performance of your service and reduce the load on the system.

Say for example that you have a page consisting of five components, each generated by a different SQL query, but for four of the five components it's the same four queries for each user so you don't have to rerun them again and again. Only one component is generated by a unique query and will not use the cache.

META: HTML::Mason docs (v 8.0) said Mason was 2-3 times slower than pure mod_perl, implying that the power & convenience made up for this.

META: Should also mention Embperl (especially since its C + XS)



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Efficient Work with Databases under mod_perl

Most of the mod_perl enabled servers work with database engines, so in this section we will learn about two things: how mod_perl makes working with databases faster and a few tips for a more efficient DBI coding in Perl. (DBI provides an identical Perl interface to many database implementations.)



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Persistent DB Connections

Another popular use of mod_perl is to take advantage of its ability to maintain persistent open database connections.

You want to have a persistent database connection because the most expensive part of a network transaction for most databases is the business of building and tearing down connections.

Of course the persistence doesn't help with the latency problems during the actual use of the database connections. Oracle is notoriously latency-sensitive which in most cases generates a network transaction per row returned which slows things down if the query execution matches many rows. You may want to read the Tim Bunce's Advanced DBI talk at http://dbi.perl.org/doc/conferences/tim_1999/index.html which covers a lot of techniques to reduce latency.

So here is the basic approach of making the connection persistent:

  # Apache::Registry script
  -------------------------
  use strict;
  use vars qw($dbh);
  
  $dbh ||= SomeDbPackage->connect(...);

Since $dbh is a global variable for the child, once the child has opened the connection it will use it over and over again, unless you perform disconnect().

Be careful to use different names for handlers if you open connections to different databases!

Apache::DBI allows you to make a persistent database connection. With this module enabled, every connect() request to the plain DBI module will be forwarded to the Apache::DBI module. This looks to see whether a database handle from a previous connect() request has already been opened, and if this handle is still valid using the ping method. If these two conditions are fulfilled it just returns the database handle. If there is no appropriate database handle or if the ping method fails, a new connection is established and the handle is stored for later re-use. There is no need to delete the disconnect() statements from your code. They will not do anything, the Apache::DBI module overloads the disconnect() method with a NOP. When a child exits there is no explicit disconnect, the child dies and so does the database connection. You may leave the use DBI; statement inside the scripts as well.

The usage is simple -- add to httpd.conf:

  PerlModule Apache::DBI

It is important to load this module before any other DBI, DBD::* and ApacheDBI* modules!

  db.pl
  ------------
  use DBI ();
  use strict;
  
  my $dbh = DBI->connect( 'DBI:mysql:database', 'user', 'password',
                          { autocommit => 0 }
                        ) || die $DBI::errstr;
  
  ...rest of the program


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Preopening Connections at the Child Process' Fork Time

If you use DBI for DB connections, and you use Apache::DBI to make them persistent, it also allows you to preopen connections to the DB for each child with the connect_on_init() method, thus saving a connection overhead on the very first request of every child.

  use Apache::DBI ();
  Apache::DBI->connect_on_init("DBI:mysql:test",
                   "login",
                   "passwd",
                   {
                RaiseError => 1,
                PrintError => 0,
                AutoCommit => 1,
                   }
                  );

This is a simple way to have Apache children establish connections on server startup. This call should be in a startup file require()d by PerlRequire or inside a <Perl> section. It will establish a connection when a child is started in that child process. See the Apache::DBI manpage for the requirements for this method.



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Caching prepare() Statements

You can also benefit from persistent connections by replacing prepare() with prepare_cached(). That way you will always be sure that you have a good statement handle and you will get some caching benefit. The downside is that you are going to pay for DBI to parse your SQL and do a cache lookup every time you call prepare_cached().

Be warned that some databases (e.g PostgreSQL and Sybase) don't support caches of prepared plans. With Sybase you could open multiple connections to achieve the same result, although this is at the risk of getting deadlocks depending on what you are trying to do!



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mod_perl Database Performance Improving



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Analysis of the Problem

A common web application architecture is one or more application servers which handle requests from client browsers by consulting one or more database servers and performing a transform on the data. When an application must consult the database on every request, the interaction with the database server becomes the central performance issue. Spending a bit of time optimizing your database access can result in significant application performance improvements. In this analysis, a system using Apache, mod_perl, DBI, and Oracle will be considered. The application server uses Apache and mod_perl to service client requests, and DBI to communicate with a remote Oracle database.

In the course of servicing a typical client request, the application server must retrieve some data from the database and execute a stored procedure. There are several steps that need to be performed to complete the request:

 1: Connect to the database server
 2: Prepare a SQL SELECT statement
 3: Execute the SELECT statement
 4: Retrieve the results of the SELECT statement
 5: Release the SELECT statement handle
 6: Prepare a PL/SQL stored procedure call
 7: Execute the stored procedure
 8: Release the stored procedure statement handle
 9: Commit or rollback
 10: Disconnect from the database server

In this document, an application will be described which achieves maximum performance by eliminating some of the steps above and optimizing others.



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Optimizing Database Connections

A naive implementation would perform steps 1 through 10 from above on every request. A portion of the source code might look like this:

  # ...
  my $dbh = DBI->connect('dbi:Oracle:host', 'user', 'pass')
    || die $DBI::errstr;
  
  my $baz = $r->param('baz');
  
  eval {
    my $sth = $dbh->prepare(qq{
        SELECT foo 
              FROM bar 
             WHERE baz = $baz
    });
    $sth->execute;
  
    while (my @row = $sth->fetchrow_array) {
        # do HTML stuff
    }
    
    $sth->finish;
  
    my $sph = $dbh->prepare(qq{
        BEGIN
            my_procedure(
                arg_in => $baz
            );
        END;
    });
    $sph->execute;
    $sph->finish;
    
    $dbh->commit;
  };
  if ($@) {
    $dbh->rollback;
  }
  
  $dbh->disconnect;
  # ...

In practice, such an implementation would have hideous performance problems. The majority of the execution time of this program would likely be spent connecting to the database. An examination shows that step 1 is comprised of many smaller steps:

 1: Connect to the database server
 1a: Build client-side data structures for an Oracle connection
 1b: Look up the server's alias in a file
 1c: Look up the server's hostname
 1d: Build a socket to the server
 1e: Build server-side data structures for this connection

The naive implementation waits for all of these steps to happen, and then throws away the database connection when it is done! This is obviously wasteful, and easily rectified. The best solution is to hoist the database connection step out of the per-request lifecycle so that more than one request can use the same database connection. This can be done by connecting to the database server once, and then not disconnecting until the Apache child process exits. The Apache::DBI module does this transparently and automatically with little effort on the part of the programmer.

Apache::DBI intercepts calls to DBI's connect and disconnect methods and replaces them with its own. Apache::DBI caches database connections when they are first opened, and it ignores disconnect commands. When an application tries to connect to the same database, Apache::DBI returns a cached connection, thus saving the significant time penalty of repeatedly connecting to the database. You will find a full treatment of Apache::DBI at Persistent DB Connections

When Apache::DBI is in use, none of the code in the example needs to change. The code is upgraded from naive to respectable with the use of a simple module! The first and biggest database performance problem is quickly dispensed with.



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Utilizing the Database Server's Cache

Most database servers, including Oracle, utilize a cache to improve the performance of recently seen queries. The cache is keyed on the SQL statement. If a statement is identical to a previously seen statement, the execution plan for the previous statement is reused. This can be a considerable improvement over building a new statement execution plan.

Our respectable implementation from the last section is not making use of this caching ability. It is preparing the statement:

  SELECT foo FROM bar WHERE baz = $baz

The problem is that $baz is being read from an HTML form, and is therefore likely to change on every request. When the database server sees this statement, it is going to look like:

  SELECT foo FROM bar WHERE baz = 1

and on the next request, the SQL will be:

  SELECT foo FROM bar WHERE baz = 42

Since the statements are different, the database server will not be able to reuse its execution plan, and will proceed to make another one. This defeats the purpose of the SQL statement cache.

The application server needs to make sure that SQL statements which are the same look the same. The way to achieve this is to use placeholders and bound parameters. The placeholder is a blank in the SQL statement, which tells the database server that the value will be filled in later. The bound parameter is the value which is inserted into the blank before the statement is executed.

With placeholders, the SQL statement looks like:

  SELECT foo FROM bar WHERE baz = :baz

Regardless of whether baz is 1 or 42, the SQL always looks the same, and the database server can reuse its cached execution plan for this statement. This technique has eliminated the execution plan generation penalty from the per-request runtime. The potential performance improvement from this optimization could range from modest to very significant.

Here is the updated code fragment which employs this optimization:

  # ...
  my $dbh = DBI->connect('dbi:Oracle:host', 'user', 'pass')
    || die $DBI::errstr;
  
  my $baz = $r->param('baz');
  
  eval {
    my $sth = $dbh->prepare(qq{
        SELECT foo 
              FROM bar 
             WHERE baz = :baz
    });
    $sth->bind_param(':baz', $baz);
    $sth->execute;
  
    while (my @row = $sth->fetchrow_array) {
        # do HTML stuff
    }
    
    $sth->finish;
  
    my $sph = $dbh->prepare(qq{
        BEGIN
            my_procedure(
                arg_in => :baz
            );
        END;
    });
    $sph->bind_param(':baz', $baz);
    $sph->execute;
    $sph->finish;
    
    $dbh->commit;
  };
  if ($@) {
    $dbh->rollback;
  }
  # ...


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Eliminating SQL Statement Parsing

The example program has certainly come a long way and the performance is now probably much better than that of the first revision. However, there is still more speed that can be wrung out of this server architecture. The last bottleneck is in SQL statement parsing. Every time DBI's prepare() method is called, DBI parses the SQL command looking for placeholder strings, and does some housekeeping work. Worse, a context has to be built on the client and server sides of the connection which the database will use to refer to the statement. These things take time, and by eliminating these steps the time can be saved.

To get rid of the statement handle construction and statement parsing penalties, we could use DBI's prepare_cached() method. This method compares the SQL statement to others that have already been executed. If there is a match, the cached statement handle is returned. But the application server is still spending time calling an object method (very expensive in Perl), and doing a hash lookup. Both of these steps are unnecessary, since the SQL is very likely to be static and known at compile time. The smart programmer can take advantage of these two attributes to gain better database performance. In this example, the database statements will be prepared immediately after the connection to the database is made, and they will be cached in package scalars to eliminate the method call.

What is needed is a routine that will connect to the database and prepare the statements. Since the statements are dependent upon the connection, the integrity of the connection needs to be checked before using the statements, and a reconnection should be attempted if needed. Since the routine presented here does everything that Apache::DBI does, it does not use Apache::DBI and therefore has the added benefit of eliminating a cache lookup on the connection.

Here is an example of such a package:

  package My::DB;
  
  use strict;
  use DBI ();
  
  sub connect {
    if (defined $My::DB::conn) {
        eval {
            $My::DB::conn->ping;
        };
        if (!$@) {
            return $My::DB::conn;
        }
    }
  
    $My::DB::conn = DBI->connect(
        'dbi:Oracle:server', 'user', 'pass', {
            PrintError => 1,
            RaiseError => 1,
            AutoCommit => 0
        }
    ) || die $DBI::errstr; #Assume application handles this
  
    $My::DB::select = $My::DB::conn->prepare(q{
        SELECT foo
          FROM bar
         WHERE baz = :baz
    });
    
    $My::DB::procedure = $My::DB::conn->prepare(q{
        BEGIN
            my_procedure(
                arg_in => :baz
            );
        END;
    });
  
    return $My::DB::conn;
  }
  
  1;

Now the example program needs to be modified to use this package.

  # ...
  my $dbh = My::DB->connect;
  
  my $baz = $r->param('baz');
  
  eval {
    my $sth = $My::DB::select;
    $sth->bind_param(':baz', $baz);
    $sth->execute;
  
    while (my @row = $sth->fetchrow_array) {
        # do HTML stuff
    }
  
    my $sph = $My::DB::procedure;
    $sph->bind_param(':baz', $baz);
    $sph->execute;
     
    $dbh->commit;
  };
  if ($@) {
    $dbh->rollback;
  }
  # ...

Notice that several improvements have been made. Since the statement handles have a longer life than the request, there is no need for each request to prepare the statement, and no need to call the statement handle's finish method. Since Apache::DBI and the prepare_cached() method are not used, no cache lookups are needed.



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Conclusion

The number of steps needed to service the request in the example system has been reduced significantly. In addition, the hidden cost of building and tearing down statement handles and of creating query execution plans is removed. Compare the new sequence with the original:

 1: Check connection to database
 2: Bind parameter to SQL SELECT statement
 3: Execute SELECT statement
 4: Fetch rows
 5: Bind parameters to PL/SQL stored procedure
 6: Execute PL/SQL stored procedure
 7: Commit or rollback

It is probably possible to optimize this example even further, but I have not tried. It is very likely that the time could be better spent improving your database indexing scheme or web server buffering and load balancing.



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Using 3rd Party Applications

It's been said that no one can do everything well, but one can do something specific extremely well. This seems to be true for many software applications, when you don't try to do everything but instead concentrate on something specific you can do it really well.

Based on the above introduction, while the mod_perl server can do many many things, there are other applications (or Apache server modules) that can do some specific operations faster or do a really great job for the mod_perl server by unloading it when doing some operations by themselves.

Let's take a look at a few of these.



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Proxying the mod_perl Server

Proxy gives you a great performance increase in most cases. It's discussed in the section Adding a Proxy Server in http Accelerator Mode.



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Upload and Download of Big Files

You don't want to tie up your precious mod_perl backend server children doing something as long and simple as transferring a file, especially a big one. The overhead saved by mod_perl is typically under one second, which is an enormous saving for the scripts whose run time is under one second. The user won't really see any important performance benefits from mod_perl, since the upload may take up to several minutes.

If some particular script's main functionality is the uploading or downloading of big files, you probably want it to be executed on a plain apache server under mod_cgi (i.e. performing this operation on the front-end server, if you use a dual-server setup.

This of course assumes that the script requires none of the functionality of the mod_perl server, such as custom authentication handlers.



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Apache/mod_perl Build Options

It's important how you build mod_perl enabled Apache. It influences the size of the httpd executable, some irrelevant modules might slow the performance.

[ReaderMETA: Any other building time things that influence performance?]



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mod_perl Process Size as a Function of Compiled in C Modules and mod_perl Features

You might wonder whether it's better to compile in only the required modules and mod_perl hooks, or it doesn't really matter. To answer on this question lets first make a few compilation and compare the results.

So we are going to build mod_perl starting with:

  % perl Makefile.PL APACHE_SRC=../apache_x.x.x/src \
         DO_HTTPD=1 USE_APACI=1

and followed by one of these option groups:

  1. Default

    no arguments

  2. Minimum
      APACI_ARGS='--disable-module=env, \
                  --disable-module=negotiation, \
                  --disable-module=status, \
                  --disable-module=info, \
                  --disable-module=include, \
                  --disable-module=autoindex, \
                  --disable-module=dir, \
                  --disable-module=cgi, \
                  --disable-module=asis, \
                  --disable-module=imap, \
                  --disable-module=userdir, \
                  --disable-module=access, \
                  --disable-module=auth'
  3. Everything
      EVERYTHING=1
  4. Everything + Debug
      EVERYTHING=1 PERL_DEBUG=1

After re-compiling with arguments of each of these groups, we can summarize the results:

  Build group    httpd size (bytes)  Difference
  ---------------------------------------------
  Minimum              892928         +     0
  Default              994316         +101388
  Everything          1044432         +151504
  Everything+Debug    1162100         +269172

Indeed when you strip most of the default things, the server size is slimmer. But the savings are insignificant since you don't multiply the added size by the number of child processes if your OS supports sharing memory. The parent processes is a little bigger, but it shares these memory pages with its child processes. Of course not everything will be shared, if some module you add does some process memory modification particular to the process, but the most will.

And of course this was just an example to show the difference is size. It doesn't mean that you can everything away, since there will be Apache modules and mod_perl options that you won't be able to work without.

But as a good system administrator's rule says: "Run the absolute minimum of the applications. If you don't know or need something, disable it". Following this rule to decide on the required Apache components and disabling the unneeded default components, makes you a good Apache administrator.



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Perl Build Options

The Perl interpreter lays in the brain of the mod_perl server and if we can optimize perl into doing things faster under mod_perl we make the whole server faster. Generally, optimizing the Perl interpreter means enabling or disabling some command line options. Let's see a few important ones.



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-DTWO_POT_OPTIMIZE and -DPACK_MALLOC Perl Build Options

Newer Perl versions also have build time options to reduce runtime memory consumption. These options might shrink the size of your httpd by about 150k -- quite a big number if you remember to multiply it by the number of children you use.

The -DTWO_POT_OPTIMIZE macro improves allocations of data with size close to a power of two; but this works for big allocations (starting with 16K by default). Such allocations are typical for big hashes and special-purpose scripts, especially image processing.

Perl memory allocation is by bucket with sizes close to powers of two. Because of these the malloc() overhead may be big, especially for data of size exactly a power of two. If PACK_MALLOC is defined, perl uses a slightly different algorithm for small allocations (up to 64 bytes long), which makes it possible to have overhead down to 1 byte for allocations which are powers of two (and appear quite often).

Expected memory savings (with 8-byte alignment in alignbytes) is about 20% for typical Perl usage. Expected slowdown due to additional malloc() overhead is in fractions of a percent and hard to measure, because of the effect of saved memory on speed.

You will find these and other memory improvement details in perl5004delta.pod.

Important: both options are On by default in perl versions 5.005 and higher.



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-Dusemymalloc Perl Build Option

You have a choice to use the native or Perl's own malloc() implementation. The choice depends on your Operating System. Unless you know which of the two is better on yours, you better try both and compare the benchmarks.

To build without Perl's malloc(), you can use the Configure command:

  % sh Configure -Uusemymalloc"

Note that:

  -U == undefine usemymalloc (use system malloc)
  -D == define   usemymalloc (use Perl's malloc)

It seems that Linux still defaults to system malloc so you might want to configure Perl with -Dusemymalloc. Perl's malloc is not much of a win under linux, but makes a huge difference under Solaris.



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Architecture Specific Compile Options

When you build Apache and Perl you can optimize the compiled applications to take the benefits of your machine's architecture.

Everything depends on the kind of compiler that you use, the kind of CPU and

For example if you use gcc(1) you might want to use:

Test your applications thoroughly when you change the default optimization flags, especially when you go beyond -02. It's possible that the optimization will make the code work incorrectly and/or cause segmentation faults.

See your preferred compiler's man page for detailed information about optimization.



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Maintainers

Maintainer is the person(s) you should contact with updates, corrections and patches.



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Authors

Only the major authors are listed above. For contributors see the Changes file.






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