It's a known fact that programmers spend a lot of time debugging their code. Sometimes we spend more time debugging code than writing it. The lion's share of the time spent on debugging is spent on finding the cause of the bug and trying to reproduce the bug at will. Usually it takes little time to fix the problem once it's understood.
A typical Perl program relies on many other modules written by other developers. Hence, no matter how good your code is, often you have to deal with bugs in the code written by someone else. No matter how hard you try to avoid learning to debug, you will have to do it at some point. And the earlier you acquire the skills, the better.
There are several levels of debugging complexity. The basic level is when Perl terminates the program during the compilation phase, before it tries to run the resulting byte code. This usually happens because there are syntax errors in the code, or perhaps because a used module is missing. Sometimes it takes quite an effort to solve these problems, since code that uses Apache core modules generally won't compile when executed from the shell. Later we will learn how to solve syntax problems in mod_perl code quite easily.
Once the program compiles and starts to run, various runtime errors may happen, usually when Perl tries to interact with external resources (e.g., trying to open a file or to open a connection to a database). If the code validates whether such external resource calls succeed and aborts the program with die( ) if they do not (including a useful error message, as we explained at the beginning of the chapter), there is nothing to debug here, because the error message gives us all the needed information. These are not bugs in our code, and it's expected that they may happen. However, if the error message is incomplete (e.g., if you didn't include $! in the error message when attempting to open a file), or the program continues to run, ignoring the failed call, then you have to figure out where the badly written code is and correct it to abort on the failure, properly reporting the problem.
Of course, there are cases where a failure to do something is not fatal. For example, consider a program that tries to open a connection to a database, and it's known that the database is being stopped every so often for maintenance. Here, the program may choose to try again and again until the database becomes available and aborts itself only after a certain timeout period. In such cases we hope that the logic is properly implemented, so it won't lead to mysterious, hard-to-detect bugs.
If the running program is properly handling external resource calls, it may still be prone to internal logical errors—i.e., when the program doesn't do what you thought you had programmed it to do. These are somewhat harder to solve than simple syntax errors, especially when there is a lot of code to be inspected and reviewed, but it's just a matter of time. Perl can help a lot; typos can often be found simply by enabling warnings. For example, if you wanted to compare two numbers, but you omitted the second = character so that you had something like if ($yes = 1) instead of if ($yes = = 1), with warnings enabled, Perl will warn you that you may have meant = =.
The next level is when the program does what it's expected to do most of the time, but occasionally misbehaves. Often you'll find that print( ) statements or the Perl debugger can help, but inspection of the code generally doesn't. Sometimes it's easy to debug with print( ), dumping your data structures to a log file at some point, but typing the debug messages can become very tedious. That's where the Perl debugger comes into its own.
While print( )statements always work, running the Perl debugger for CGI-style scripts might be quite a challenge. But with the right knowledge and tools handy, the debugging process becomes much easier. Unfortunately, there is no one easy way to debug your programs, as the debugging depends entirely on your code. It can be a nightmare to debug really complex and obscure code, but as your style matures you can learn ways to write simpler code that is easier to debug. You will probably find that when you write simpler, clearer code it does not need so much debugging in the first place.
One of the most difficult cases to debug is when the process just terminates in the middle of processing a request and aborts with a "Segmentation fault" error (possibly dumping core, by creating a file called core in the current directory of the process that was running). Often this happens when the program tries to access a memory area that doesn't belong to it. This is something that you rarely see with plain Perl scripts, but it can easily happen if you use modules whose guts are written in C or C++ and something goes wrong with them. Occasionally you will come across a bug in mod_perl itself (mod_perl is written in C and makes extensive use of XS macros).
In the following sections we will cover a selection of problems in detail, thoroughly discussing them and presenting a few techniques to solve them.
While developing code, we sometimes make syntax errors, such as forgetting to put a comma in a list or a semicolon at the end of a statement.
One approach to locating syntactically incorrect code is to execute the script from the shell with the -c flag:
panic% perl -c test.pl
This tells Perl to check the syntax but not to run the code (actually, it will execute BEGIN blocks, END blocks, and use( ) calls, because these are considered as occurring outside the execution of your program, and they can affect whether your program compiles correctly or not).[50]
[50]Perl 5.6.0 has introduced a new special variable, $^C, which is set to true when Perl is run with the -c flag; this provides an opportunity to have some further control over BEGIN and END blocks during syntax checking.
When checking syntax in this way it's also a good idea to add the -w switch to enable warnings:
panic% perl -cw test.pl
If there are errors in the code, Perl will report the errors and tell you at which line numbers in your script the errors were found. For example, if we create a file test.pl with the contents:
@list = ('foo' 'bar');
and do syntax validation from the command line:
panic% perl -cw test.pl String found where operator expected at test.pl line 1, near "'foo' 'bar'" (Missing operator before 'bar'?) syntax error at test.pl line 1, near "'foo' 'bar'" test.pl had compilation errors.
we can learn from the error message that we are missing an operator before the 'bar' string, which is of course a comma in this case. If we place the missing comma between the two strings:
@list = ('foo', 'bar');
and run the test again:
panic% perl -cw test.pl Name "main::list" used only once: possible typo at test.pl line 1. test.pl syntax OK
we can see that the syntax is correct now. But Perl still warns us that we have some variable that is defined but not used. Is this a bug? Yes and no—it's what we really meant in this example, but our example doesn't actually do anything, so Perl is probably right to complain.
The next step is to execute the script, since in addition to syntax errors there may be runtime errors. These are usually the errors that cause the "Internal Server Error" response when a page is requested by a client's browser. With plain CGI scripts (running under mod_cgi) it's the same as running plain Perl scripts—just execute them and see if they work.
The whole thing is quite different with scripts that use Apache::* modules. These can be used only from within the mod_perl server environment. Such scripts rely on other code, and an environment that isn't available if you attempt to execute the script from the shell. There is no Apache request object available to the code when it is executed from the shell.
If you have a problem when using Apache::* modules, you can make a request to the script from a browser and watch the errors and warnings as they are logged to the error_log file. Alternatively, you can use the Apache::FakeRequest module, which tries to emulate a request and makes it possible to debug some scripts outside the mod_perl environment, as we will see in the next section.
Apache::FakeRequest is used to set up an empty Apache request object that can be used for debugging. The Apache::FakeRequest methods just set internal variables with the same names as the methods and returns the values of the internal variables. Initial values for methods can be specified when the object is created. The print( ) method prints to STDOUT.
Subroutines for Apache constants are also defined so that you can use Apache::Constants while debugging, although the values of the constants are hardcoded rather than extracted from the Apache source code.
Example 21-2 is a very simple module that prints a brief message to the client's browser.
package Book::Example; use Apache::Constants qw(OK); sub handler { my $r = shift; $r->send_http_header('text/plain'); print "You are OK ", $r->get_remote_host, "\n"; return OK; } 1;
You cannot debug this module unless you configure the server to run it, by calling its handler from somewhere. So, for example, you could put in httpd.conf:
<Location /ex> SetHandler perl-script PerlHandler Book::Example </Location>
Then, after restarting the server, you could start a browser, request the location http://localhost/ex, and examine the output. Tedious, no?
With the help of Apache::FakeRequest, you can write a little script that will emulate a request and return the output (see Example 21-3).
#!/usr/bin/perl use Apache::FakeRequest ( ); use Book::Example ( ); my $r = Apache::FakeRequest->new('get_remote_host'=>'www.example.com'); Book::Example::handler($r);
When you execute the script from the command line, you will see the following output as the body of the response:
You are OK www.example.com
As you can see, when Apache::FakeRequest was initialized, we hardcoded the Apache method get_remote_host( ) with a static value.
At the time of this writing, Apache::FakeRequest is far from being complete, but you may still find it useful.
If while developing your code you have to switch back and forth between the normal and fake modes, you may want to start your code in this way:
use constant MOD_PERL => $ENV{MOD_PERL}; my $r; if (MOD_PERL) { $r = Apache->request; } else { require Apache::FakeRequest; $r = Apache::FakeRequest->new; }
When you run from the command line, the fake request will be used; otherwise, the usual method will be used.
The universal debugging tool across nearly all platforms and programming languages is printf( ) (or equivalent output functions). This function can send data to the console, a file, an application window, and so on. In Perl we generally use the print( ) function. With an idea of where and when the bug is triggered, a developer can insert print( )statements into the source code to examine the value of data at certain stages of execution.
However, it is rather difficult to anticipate all the possible directions a program might take and what data might cause trouble. In addition, inline debugging code tends to add bloat and degrade the performance of an application and can also make the code harder to read and maintain. Furthermore, you have to comment out or remove the debugging print( ) calls when you think that you have solved the problem, and if later you discover that you need to debug the same code again, you need at best to uncomment the debugging code lines or, at worst, to write them again from scratch.
The constant pragma helps here. You can leave some debug printings in production code, without adding extra processing overhead, by using constants. For example, while developing the code, you can define a constant DEBUG whose value is 1:
package Foo; use constant DEBUG => 1; ... warn "entering foo" if DEBUG; ...
The warning will be printed, since DEBUG returns true. In production you just have to turn off the constant:
use constant DEBUG => 0;
When the code is compiled with a false DEBUG value, all those statements that are to be executed if DEBUG has a true value will be removed on the fly at compile time, as if they never existed. This allows you to keep some of the important debug statements in the code without any adverse impact on performance.
But what if you have many different debug categories and you want to be able to turn them on and off as you need them? In this case, you need to define a constant for each category. For example:
use constant DEBUG_TEMPLATE => 1; use constant DEBUG_SESSION => 0; use constant DEBUG_REQUEST => 0;
Now if in your code you have these three debug statements:
warn "template" if DEBUG_TEMPLATE; warn "session" if DEBUG_SESSION; warn "request" if DEBUG_REQUEST;
only the first one will be executed, as it's the only one that has a condition that evaluates to true.
Let's look at a few examples where we use print( ) to debug some problem.
In one of our applications, we wrote a function that returns a date from one week ago. This function (including the code that calls it) is shown in Example 21-4.
print "Content-type: text/plain\n\n"; print "A week ago the date was ",date_a_week_ago( ),"\n"; # return a date one week ago as a string in format: MM/DD/YYYY sub date_a_week_ago { my @month_len = (31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31); my($day, $month, $year) = (localtime)[3..5]; for (my $j = 0; $j < 7; $j++) { $day--; if ($day = = 0) { $month--; if ($month = = 0) { $year--; $month = 12; } # there are 29 days in February in a leap year $month_len[1] = ($year % 400 = = 0 or ($year % 4 = = 0 and $year % 100)) ? 29 : 28; # set $day to be the last day of the previous month $day = $month_len[$month - 1]; } } return sprintf "%02d/%02d/%04d", $month, $day, $year+1900; }
This code is pretty straightforward. We get today's date and subtract 1 from the value of the day we get, updating the month and the year on the way if boundaries are being crossed (end of month, end of year). If we do it seven times in a loop, at the end we should get a date from a week ago.
Note that since localtime( ) returns the year as a value of current_year-1900 (which means that we don't have a century boundary to worry about), if we are in the middle of the first week of the year 2000, the value of $year returned by localtime( ) will be 100 and not 0, as one might mistakenly assume. So when the code does $year-- it becomes 99, not -1. At the end, we add 1900 to get back the correct four-digit year format. (If you plan to work with years before 1900, add 1900 to $year before the for loop.)
Also note that we have to account for leap years, where there are 29 days in February. For the other months, we have prepared an array containing the month lengths. A specific year is a leap year if it is either evenly divisible by 400 or evenly divisible by 4 and not evenly divisible by 100. For example, the year 1900 was not a leap year, but the year 2000 was a leap year. Logically written:
print ($year % 400 = = 0 or ($year % 4 = = 0 and $year % 100)) ? 'Leap' : 'Not Leap';
Now when we run the script and check the result, we see that something is wrong. For example, if today is 10/23/1999, we expect the above code to print 10/16/1999. In fact, it prints 09/16/1999, which means that we have lost a month. The above code is buggy!
Let's put a few debug print( ) statements in the code, near the $month variable:
sub date_a_week_ago { my @month_len = (31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31); my($day, $month, $year) = (localtime)[3..5]; print "[set] month : $month\n"; # DEBUG for (my $j = 0; $j < 7; $j++) { $day--; if ($day = = 0) { $month--; if ($month = = 0) { $year--; $month = 12; } print "[loop $i] month : $month\n"; # DEBUG # there are 29 days in February in a leap year $month_len[1] = ($year % 400 = = 0 or ($year % 4 = = 0 and $year % 100)) ? 29 : 28; # set $day to be the last day of the previous month $day = $month_len[$month - 1]; } } return sprintf "%02d/%02d/%04d", $month, $day, $year+1900; }
When we run it we see:
[set] month : 9
This is supposed to be the number of the current month (10). We have spotted a bug, since the only code that sets the $month variable consists of a call to localtime( ). So did we find a bug in Perl? Let's look at the manpage of the localtime( ) function:
panic% perldoc -f localtime Converts a time as returned by the time function to a 9-element array with the time analyzed for the local time zone. Typically used as follows: # 0 1 2 3 4 5 6 7 8 ($sec,$min,$hour,$mday,$mon,$year,$wday,$yday,$isdst) = localtime(time); All array elements are numeric, and come straight out of a struct tm. In particular this means that $mon has the range 0..11 and $wday has the range 0..6 with Sunday as day 0. Also, $year is the number of years since 1900, that is, $year is 123 in year 2023, and not simply the last two digits of the year. If you assume it is, then you create non-Y2K-compliant programs--and you wouldn't want to do that, would you? [more info snipped]
This reveals that if we want to count months from 1 to 12 and not 0 to 11 we are supposed to increment the value of $month. Among other interesting facts about localtime( ), we also see an explanation of $year, which, as we've mentioned before, is set to the number of years since 1900.
We have found the bug in our code and learned new things about localtime( ). To correct the above code, we just increment the month after we call localtime( ):
my($day, $month, $year) = (localtime)[3..5]; $month++;
Other places where programmers often make mistakes are conditionals and loop statements. For example, will the block in this loop:
my $c = 0; for (my $i=0; $i <= 3; $i++) { $c += $i; }
be executed three or four times?
If we plant the print( ) debug statement:
my $c = 0; for (my $i=0; $i <= 3; $i++) { $c += $i; print $i+1,"\n"; }
and execute it:
1 2 3 4
we see that it gets executed four times. We could have figured this out by inspecting the code, but what happens if instead of 3, there is a variable whose value is known only at runtime? Using debugging print( )statements helps to determine whether to use < or <= to get the boundary condition right.
Using idiomatic Perl makes things much easier:
panic% perl -le 'my $c=0; $c += $_, print $_+1 for 0..3;'
Here you can plainly see that the loop is executed four times.
The same goes for conditional statements. For example, assuming that $a and $b are integers, what is the value of this statement?
$c = $a > $b and $a < $b ? 1 : 0;
One might think that $c is always set to zero, since:
$a > $b and $a < $b
is a false statement no matter what the values of $a and $b are. But C$ is not set to zero—it's set to 1 (a true value) if $a > $b; otherwise, it's set to undef (a false value). The reason for this behavior lies in operator precedence. The operator and (AND) has lower precedence than the operator = (ASSIGN); therefore, Perl sees the statement like this:
($c = ($a > $b) ) and ( $a < $b ? 1 : 0 );
which is the same as:
if ($c = $a > $b) { $a < $b ? 1 : 0; }
So the value assigned to $c is the result of the logical expression:
$a > $b
Adding some debug printing will reveal this problem. The solutions are, of course, either to use parentheses to explicitly express what we want:
$c = ($a > $b and $a < $b) ? 1 : 0;
or to use a higher-precedence AND operator:
$c = $a > $b && $a < $b ? 1 : 0;
Now $c is always set to 0 (as presumably we intended).[51]
[51]For more traps, refer to the perltrap manpage.
Sometimes we need to peek into complex data structures, and trying to print them out can be tricky. That's where Data::Dumper comes to the rescue. For example, if we create this complex data structure:
$data = { array => [qw(apple banana clementine damson)], hash => { food => "vegetables", drink => "juice", }, };
how do we print it out? Very easily:
use Data::Dumper; print Dumper $data;
What we get is a pretty-printed $data:
$VAR1 = { 'hash' => { 'food' => 'vegetables', 'drink' => 'juice' }, 'array' => [ 'apple', 'banana', 'clementine', 'damson' ] };
Suppose while writing this example we made a mistake and wrote:
array => qw(apple banana clementine damson),
instead of:
array => [qw(apple banana clementine damson)],
When we pretty-printed the contents of $data we would immediately see our mistake:
$VAR1 = { 'banana' => 'clementine', 'damson' => 'hash', 'HASH(0x80cd79c)' => undef, 'array' => 'apple' };
That's not what we want—we have spotted the bug and can easily correct it.
You can use:
print STDERR Dumper $data;
or:
warn Dumper $data;
instead of printing to STDOUT, to have all the debug messages in the error_log file. This makes it even easier to debug your code, since the real output (which should normally go to the browser) is not mixed up with the debug output when the code is executed under mod_perl.
Don't strive for elegant, clever code. Try to develop a good coding style by writing code that is concise, yet easy to understand. It's much easier to find bugs in concise, simple code, and such code tends to have fewer bugs.
The "one week ago" example from the previous section is not concise. There is a lot of redundancy in it, and as a result it is harder to debug than it needs to be. Here is a condensed version of the main loop:
for (0..6) { next if --$day; $year--, $month=12 unless --$month; $day = $month != 2 ? $month_len[$month-1] : ($year % 400 = = 0 or ($year % 4 = = 0 and $year % 100)) ? 29 : 28; }
This version may seem quite difficult to understand and even harder to maintain, but for those who are used to reading idiomatic Perl, part of this code is easier to understand.
Larry Wall, the author of Perl, is a linguist. He tried to define the syntax of Perl in a way that makes working in Perl much like working in English. So it's a good idea to learn Perl's coding idioms—some of them might seem odd at first, but once you get used to them, you will find it difficult to understand how you could have lived without them. We'll present just a few of the more common Perl coding idioms here.
You should try to write code that is readable and avoids redundancy. For example, it's better to write:
unless ($i) {...}
than:
if ($i = = 0) {...}
if you want to just test for truth.
Use a concise, Perlish style:
for my $j (0..6) {...}
instead of the syntax used in some other languages:
for (my $j=0; $j<=6; $j++) {...}
It's much simpler to write and comprehend code like this:
print "something" if $debug;
than this:
if ($debug) { print "something"; }
A good style that improves understanding and readability and reduces the chances of having a bug is shown below, in the form of yet another rewrite of our "one week ago" code:
for (0..6) { $day--; next if $day; $month--; unless ($month){ $year--; $month=12 } if($month = = 2){ # February $day = ($year % 400 = = 0 or ($year % 4 = = 0 and $year % 100)) ? 29 : 28; } else { $day = $month_len[$month-1]; } }
This is a happy medium between the excessively verbose style of the first version and the very obscure second version.
After debugging this obscure code for a while, we came up with a much simpler two-liner, which is much faster and easier to understand:
sub date_a_week_ago { my($day, $month, $year) = (localtime(time-7*24*60*60))[3..5]; return sprintf "%02d/%02d/%04d", $month+1, $day, $year+1900; }
Just take the current date in seconds since epoch as time( ) returns, subtract a week in seconds (7661 × 24 × 60 × 60),[52] and feed the result to localtime( ). Voilà—we have the date of one week ago!
[52]Perl folds the constants at compile time.
Why is the last version important, when the first one works just fine? Not because of performance issues (although this last one is twice as fast as the first), but because there are more chances to have a bug in the first version than there are in the last one.
Of course, instead of inventing the date_a_week_ago( ) function and spending all this time debugging it, we could have just used a standard module from CPAN to provide the same functionality (with zero debugging time). In this case, Date::Calc comes to the rescue,[53] and we will write the code as:
[53]See also Class::Date and Date::Manip.
use Date::Calc; sub date_a_week_ago { my($year,$month,$day) = Date::Calc::Add_Delta_Days(Date::Calc::Today, -7); return sprintf "%02d/%02d/%04d", $month, $day, $year; }
We simply use Date::Calc::Today( ), which returns a list of three values—year, month, and day—which are immediately fed into the function Date::Calc::Add_Delta_Days( ). This allows us to get the date N days from now in either direction. We use -7 to ask for a date from one week ago. Since we are relying on this standard CPAN module, there is not much to debug here; the function has no complicated logic where one can expect bugs. In contrast, our original implementation was really difficult to understand, and it was very easy to make mistakes.
We will use this example once again to stress that it's better to use standard modules than to reinvent them.
As we saw earlier, it's almost always possible to debug code with the help of print( ). However, it is impossible to anticipate all the possible paths of execution through a program, and difficult to know what code to suspect when trouble occurs. In addition, inline debugging code tends to add bloat and degrade the performance of an application, although most applications offer inline debugging as a compile-time option to avoid these performance hits. In any case, this information tends to be useful only to the programmer who added the print( )statements in the first place.
Sometimes you must debug tens of thousands of lines of Perl in an application, and while you may be a very experienced Perl programmer who can understand Perl code quite well just by looking at it, no mere mortal can even begin to understand what will actually happen in such a large application until the code is running. So to begin with you just don't know where to add your trusty print( )statements to see what is happening inside.
The most effective way to track down a bug is often to run the program inside an interactive debugger. Most programming languages have such tools available, allowing programmers to see what is happening inside an application while it is running. The basic features of any interactive debugger allow you to:
Stop at a certain point in the code, based on a routine name or source file and line number (this point is called a break point).
Stop at a certain point in the code, based on conditions such as the value of a given variable (this is called a conditional break point).
Perform an action without stopping, based on the criteria above.
View and modify the values of variables at any time.
Provide context information such as stack traces and source views.
It takes practice to learn the most effective ways of using an interactive debugger, but the time and effort will be paid back many times in the long run.
Perl comes with an interactive debugger called perldb. Giving control of your Perl program to the interactive debugger is simply a matter of specifying the -d command-line switch. When this switch is used, Perl inserts debugging hooks into the program syntax tree, but it leaves the job of debugging to a Perl module separate from the Perl binary itself.
We will start by reviewing a few of the basic concepts and commands provided by Perl's interactive debugger. These examples are all run from the command line, independent of mod_perl, but they will still be relevant when we work within Apache.
It might be useful to keep the perldebug manpage handy for reference while reading this section, and for future debugging sessions on your own.
The interactive debugger will attach to the current terminal and present you with a prompt just before the first program statement is executed. For example:
panic% perl -d -le 'print "mod_perl rules the world"' Loading DB routines from perl5db.pl version 1.0402 Emacs support available. Enter h or `h h' for help. main::(-e:1): print "mod_perl rules the world" DB<1>
The source line shown is the line that Perl is about to execute. To single step—i.e., execute one line at a time—use the next command (or just n). Each time you enter something in the debugger, you must finish by pressing the Return key. This will cause the line to be executed, after which execution will stop and the next line to be executed (if any) will be displayed:
main::(-e:1): print "mod_perl rules the world" DB<1> n mod_perl rules the world Debugged program terminated. Use q to quit or R to restart, use O inhibit_exit to avoid stopping after program termination, h q, h R or h O to get additional info. DB<1>
In this case, our example code is only one line long, so we have finished interacting after the first line of code is executed. Let's try again with a slightly longer example:
my $word = 'mod_perl'; my @array = qw(rules the world); print "$word @array\n";
Save the script in a file called domination.pl and run it with the -d switch:
panic% perl -d domination.pl main::(domination.pl:1): my $word = 'mod_perl'; DB<1> n main::(domination.pl:2): my @array = qw(rules the world); DB<1>
At this point, the first line of code has been executed and the variable $word has been assigned the value mod_perl. We can check this by using the p (print) command:
main::(domination.pl:2): my @array = qw(rules the world); DB<1> p $word mod_perl
The print command is similar to Perl's built-in print( ) function, but it adds a trailing newline and outputs to the $DB::OUT file handle, which is normally opened on the terminal from which Perl was launched. Let's continue:
DB<2> n main::(domination.pl:4): print "$word @array\n"; DB<2> p @array rulestheworld DB<3> n mod_perl rules the world Debugged program terminated. Use q to quit or R to restart, use O inhibit_exit to avoid stopping after program termination, h q, h R or h O to get additional info.
Unfortunately, p @array printed rulestheworld and not rules the world, as we would prefer, but that's absolutely correct. If you print an array without expanding it first into a string it will be printed without adding the content of the $" variable (otherwise known as $LIST_SEPARATOR, if the English pragma is being used) between the elements of the array.
If you type:
print "@array";
the output will be rules the world, since the default value of the $" variable is a single space.
You should have noticed by now that there is some valuable information to the left of each executable statement:
main::(domination.pl:4): print "$word @array\n"; DB<2>
First is the current package name (in this case, main::). Next is the current filename and statement line number (domination.pl and 4, in this example). The number presented at the prompt is the command number, which can be used to recall commands from the session history, using the ! command followed by this number. For example, !1 would repeat the first command:
panic% perl -d -e0 main::(-e:1): 0 DB<1> p $] 5.006001 DB<2> !1 p $]5.006001 DB<3>
where $] is Perl's version number. As you can see, !1 prints the value of $], prepended by the command that was executed.
Notice that the code given to Perl to debug (with -e) was 0—i.e., a statement that does nothing. To use Perl as a calculator, and to experiment with Perl expressions, it is common to enter perl -de0, and then type in expressions and p (print) their results.
Things start to get more interesting as the code gets more interesting. In the script in Example 21-5, we've increased the number of source files and packages by including the standard Symbol module, along with an invocation of its gensym( ) function.
use Symbol ( ); my $sym = Symbol::gensym( ); print "$sym\n";
Now let's debug it:
panic% perl -d test_sym.pl main::(test_sym.pl:3): my $sym = Symbol::gensym( ); DB<1> n main::(test_sym.pl:5): print "$sym\n"; DB<1> n GLOB(0x80c7a44)
Note that the debugger did not stop at the first line of the file. This is because use ... is a compile-time statement, not a runtime statement. Also notice there was more work going on than the debugger revealed. That's because the next command does not enter subroutine calls, it steps over. To step into subroutine code, use the step command (or its abbreviated form, s):
panic% perl -d test_sym.pl main::(test_sym.pl:3): my $sym = Symbol::gensym( ); DB<1> s Symbol::gensym(/usr/lib/perl5/5.6.1/Symbol.pm:86): 86: my $name = "GEN" . $genseq++; DB<1>
Notice the source line information has changed to the Symbol::gensym package and the Symbol.pm file. We can carry on by hitting the Return key at each prompt, which causes the debugger to repeat the last step or next command. It won't repeat a print command, though. The debugger will eventually return from the subroutine back to our main program:
DB<1> Symbol::gensym(/usr/lib/perl5/5.6.1/Symbol.pm:87): 87: my $ref = *{$genpkg . $name}; DB<1> Symbol::gensym(/usr/lib/perl5/5.6.1/Symbol.pm:88): 88: delete $$genpkg{$name}; DB<1> Symbol::gensym(/usr/lib/perl5/5.6.1/Symbol.pm:89): 89: $ref; DB<1> main::(test_sym.pl:5): print "$sym\n"; DB<1> GLOB(0x80c7a44)
Our line-by-line debugging approach has served us well for this small program, but imagine the time it would take to step through a large application at the same pace. There are several ways to speed up a debugging session, one of which is known as setting a breakpoint.
The breakpoint command (b) is used to tell the debugger to stop at a named subroutine or at any line of any file. In this example session, at the first debugger prompt we will set a breakpoint at the Symbol::gensym subroutine, telling the debugger to stop at the first line of this routine when it is called. Rather than moving along with next or step, we give the continue command (c), which tells the debugger to execute the script without stopping until it reaches a breakpoint:
panic% perl -d test_sym.pl main::(test_sym.pl:3): my $sym = Symbol::gensym( ); DB<1> b Symbol::gensym DB<2> c Symbol::gensym(/usr/lib/perl5/5.6.1/Symbol.pm:86): 86: my $name = "GEN" . $genseq++;
Now let's imagine we are debugging a large application where Symbol::gensym might be called from any one of several places. When the subroutine breakpoint is reached, by default the debugger does not reveal where it was called from. One way to find out this information is with the stack Trace command (T):
DB<2> T $ = Symbol::gensym( ) called from file `test_sym.pl' line 3
In this example, the call stack is only one level deep, so only that call is printed. We'll look at an example with a deeper stack later. The leftmost character reveals the context in which the subroutine was called. $ represents scalar context; in other examples you may see @, which represents list context, or ., which represents void context. In our case we called:
my $sym = Symbol::gensym( );
which calls the Symbol::gensym( ) in scalar context.
Now let's make our test_sym.pl example a little more complex. First, we add a Book::World1 package declaration at the top of the script, so we are no longer working in the main:: package. Next, we add a subroutine named do_work( ), which invokes the familiar Symbol::gensym, along with another function called Symbol::qualify, and then returns a hash reference of the results. The do_work( ) routine is invoked inside a for loop, which will be run twice. The new version of the script is shown in Example 21-6.
package Book::World2; use Symbol ( ); for (1, 2) { do_work("now"); } sub do_work { my($var) = @_; return undef unless $var; my $sym = Symbol::gensym( ); my $qvar = Symbol::qualify($var); my $retval = { sym => $sym, var => $qvar, }; return $retval; } 1;
We'll start by setting a few breakpoints, then we'll use the List command (L) to display them:
panic% perl -d test_sym2.pl Book::World2::(test_sym2.pl:5): for (1, 2) { DB<1> b Symbol::qualify DB<2> b Symbol::gensym DB<3> L /usr/lib/perl5/5.6.1/Symbol.pm: 86: my $name = "GEN" . $genseq++; break if (1) 95: my ($name) = @_; break if (1)
The filename and line number of the breakpoint are displayed just before the source line itself. Because both breakpoints are located in the same file, the filename is displayed only once. After the source line, we see the condition on which to stop. In this case, as the constant value 1 indicates, we will always stop at these breakpoints. Later on you'll see how to specify a condition.
As we will see, when the continue command is executed, the execution of the program stops at one of these breakpoints, at either line 86 or line 95 of the file /usr/lib/perl5/5.6.1/Symbol.pm, whichever is reached first. The displayed code lines are the first line of each of the two subroutines from Symbol.pm. Breakpoints may be applied only to lines of runtime-executable code—you cannot, for example, put breakpoints on empty lines or comments.
In our example, the List command shows which lines the breakpoints were set on, but we cannot tell which breakpoint belongs to which subroutine. There are two ways to find this out. One is to run the continue command and, when it stops, execute the Trace command we saw before:
DB<3> c Symbol::gensym(/usr/lib/perl5/5.6.1/Symbol.pm:86): 86: my $name = "GEN" . $genseq++; DB<3> T $ = Symbol::gensym( ) called from file `test_sym2.pl' line 14 . = Book::World2::do_work('now') called from file `test_sym2.pl' line 6
So we see that this breakpoint belongs to Symbol::gensym. The other way is to ask for a listing of a range of lines from the code. For example, let's check which subroutine line 86 is a part of. We use the list (lowercase!) command (l), which displays parts of the code. The list command accepts various arguments; the one that we want to use here is a range of lines. Since the breakpoint is at line 86, let's print a few lines around that line number:
DB<3> l 85-87 85 sub gensym ( ) { 86= =>b my $name = "GEN" . $genseq++; 87: my $ref = *{$genpkg . $name};
Now we know it's the gensym subroutine, and we also see the breakpoint highlighted with the = =>b markup. We could also use the name of the subroutine to display its code:
DB<4> l Symbol::gensym 85 sub gensym ( ) { 86= =>b my $name = "GEN" . $genseq++; 87: my $ref = *{$genpkg . $name}; 88: delete $$genpkg{$name}; 89: $ref; 90 }
The delete command (d) is used to remove a breakpoint by specifying the line number of the breakpoint. Let's remove the first one we set:
DB<5> d 95
The Delete (with a capital D) command (D) removes all currently installed breakpoints.
Now let's look again at the trace produced at the breakpoint:
DB<3> c Symbol::gensym(/usr/lib/perl5/5.6.1/Symbol.pm:86): 86: my $name = "GEN" . $genseq++; DB<3> T $ = Symbol::gensym( ) called from file `test_sym2.pl' line 14 . = Book::World2::do_work('now') called from file `test_sym2.pl' line 6
As you can see, the stack trace prints the values that are passed into the subroutine. Ah, and perhaps we've found our first bug: as we can see from the first character on the second line of output from the Trace command, do_work( ) was called in void context, so the return value was discarded. Let's change the for loop to check the return value of do_work( ):
for (1, 2) { my $stuff = do_work("now"); if ($stuff) { print "work is done\n"; } }
In this session we will set a breakpoint at line 7 of test_sym2.pl, where we check the return value of do_work( ):
panic% perl -d test_sym2.pl Book::World2::(test_sym2.pl:5): for (1, 2) { DB<1> b 7 DB<2> c Book::World2::(test_sym2.pl:7): if ($stuff) { DB<2>
Our program is still small, but already it is getting more difficult to understand the context of just one line of code. The window command (w)[54] will list a few lines of code that surround the current line:
[54]In Perl 5.8.0 use l instead of w, which is used for watch-expressions.
DB<2> w 4 5: for (1, 2) { 6: my $stuff = do_work("now"); 7= =>b if ($stuff) { 8: print "work is done\n"; 9 } 10 } 11 12 sub do_work { 13: my($var) = @_;
The arrow points to the line that is about to be executed and also contains a b, indicating that we have set a breakpoint at this line.[55]
[55]Note that breakable lines of code include a colon (:) immediately after the line number.
Now, let's take a look at the value of the $stuff variable:
DB<2> p $stuff HASH(0x82b89b4)
That's not very useful information. Remember, the print command works just like the built-in print( ) function. The debugger's x command evaluates a given expression and pretty-prints the results:
DB<3> x $stuff 0 HASH(0x82b89b4) 'sym' => GLOB(0x826a944) -> *Symbol::GEN0 'var' => 'Book::World2::now'
Things seem to be okay. Let's double check by calling do_work( ) with a different value and print the results:
DB<4> x do_work('later') 0 HASH(0x82bacc8) 'sym' => GLOB(0x818f16c) -> *Symbol::GEN1 'var' => 'Book::World2::later'
We can see the symbol was incremented from GEN0 to GEN1 and the variable later was qualified, as expected.[56]
[56]You won't see the symbol printout with Perl 5.6.1, but it works fine with 5.005_03 or 5.8.0
Now let's change the test program a little to iterate over a list of arguments held in @args and print a slightly different message (see Example 21-7).
package Book::World3; use Symbol ( ); my @args = qw(now later); for my $arg (@args) { my $stuff = do_work($arg); if ($stuff) { print "do your work $arg\n"; } } sub do_work { my($var) = @_; return undef unless $var; my $sym = Symbol::gensym( ); my $qvar = Symbol::qualify($var); my $retval = { sym => $sym, var => $qvar, }; return $retval; } 1;
There are only two arguments in the list, so stopping to look at each one isn't too time-consuming, but consider the debugging pace if we had a large list of 100 or so entries. Fortunately, it is possible to customize breakpoints by specifying a condition. Each time a breakpoint is reached, the condition is evaluated, stopping only if the condition is true. In the session below, the window command shows breakable lines. The = =>symbol shows us the line of code that's about to be executed.
panic% perl -d test_sym3.pl Book::World3::(test_sym3.pl:5): my @args = qw(now later); DB<1> w 5= => my @args = qw(now later); 6: for my $arg (@args) { 7: my $stuff = do_work($arg); 8: if ($stuff) { 9: print "do your work $arg\n"; 10 } 11 } 12 13 sub do_work { 14: my($var) = @_;
We set a breakpoint at line 7 with the condition $arg eq 'later'. As we continue, the breakpoint is skipped when $arg has the value of now but not when it has the value of later:
DB<1> b 7 $arg eq 'later' DB<2> c do your work now Book::World3::(test_sym3.pl:7): my $stuff = do_work($arg); DB<2> n Book::World3::(test_sym3.pl:8): if ($stuff) { DB<2> x $stuff 0 HASH(0x82b90e4) 'sym' => GLOB(0x82b9138) -> *Symbol::GEN1 'var' => 'Book::World3::later' DB<5> c do your work later Debugged program terminated. Use q to quit or R to restart,
You should now understand enough about the debugger to try many other features on your own, with the perldebug manpage by your side. Quick online help from inside the debugger is available by typing the h command, which will display a list of the most useful commands and a short explanation of what they do.
Some installations of Perl include a readline module that allows you to work more interactively with the debugger—for example, by pressing the up arrow to see previous commands, which can then be repeated by pressing the Return key.
Devel::ptkdb is a visual Perl debugger that uses Perl/Tk for the user interface and requires a windows system like X Windows or Windows to run.
To debug a plain Perl script with Devel::ptkdb, invoke it as:
panic% perl -d:ptkdb myscript.pl
The Tk application will be loaded. Now you can do most of the debugging you did with the command-line Perl debugger, but using a simple GUI to set/remove breakpoints, browse the code, step through it, and more.
With the help of Devel::ptkdb, you can debug your CGI scripts running under mod_cgi (we'll look at mod_perl debugging later). Be sure that the web server's Perl installation includes the Tk package. To enable the debugger, change your shebang line from:
#!/usr/bin/perl -Tw
to:
#!/usr/bin/perl -Twd:ptkdb
You can debug scripts remotely if you're using a Unix-based server and if the machine where you are writing the script has an X server. The X server can be another Unix workstation, or a Macintosh or Win32 platform with an appropriate X Windows package. You must insert the following BEGINsubroutine into your script:
BEGIN { $ENV{'DISPLAY'} = "localhost:0.0" ; }
You may need to replace the localhost value with a real DNS or IP address if you aren't working at the machine itself. You must be sure that your web server has permission to open windows on your X server (see the xhost manpage for more information).
Access the web page with the browser and request the script as usual. The ptkdb window should appear on the monitor if you have correctly set the $ENV{'DISPLAY'} variable (see Figure 21-2). At this point you can start debugging your script. Be aware that the browser may time out waiting for the script to run.
To expedite debugging you may want to set your breakpoints in advance with a .ptkdbrc file and use the $DB::no_stop_at_start variable. For debugging web scripts, you may have to have the .ptkdbrc file installed in the server account's home directory (e.g., ~httpd) or whatever username the web server is running under. Also try installing a .ptkdbrc file in the same directory as the target script.
ptkdb is available from CPAN: http://www.perl.com/CPAN/authors/id/A/AE/AEPAGE/.
To debug scripts running under mod_perl noninteractively (i.e., to print the Perl execution trace), simply set the usual environment variables that control debugging.
The NonStop debugger option enables you to get some decent debugging information when running under mod_perl. For example, before starting the server:
panic% setenv PERL5OPT -d panic% setenv PERLDB_OPTS \ "NonStop=1 LineInfo=/tmp/db.out AutoTrace=1 frame=2"
Now watch /tmp/db.out for line:filename information. This is most useful for tracking those core dumps that normally leave us guessing, even with a stack trace from gdb, which we'll discuss later. db.out will show you what Perl code triggered the core dump. Refer to the perldebug manpage for more PERLDB_OPTS options.
Say we execute a simple Apache::Registryscript, test.pl:
use strict; my $r = shift; $r->send_http_header("text/plain"); $r->print("Hello");
The generated trace found in /tmp/db.out is too long to be printed here in its entirety. We will show only the part that actually executes the handler created on the fly by Apache::Registry:
entering Apache::ROOT::perl::test_2epl::handler 2: 3: entering Apache::send_http_header exited Apache::send_http_header 4: entering Apache::print exited Apache::print exited Apache::ROOT::perl::test_2epl::handler
You can see how Perl executes this script—first the send_http_header( ) function is executed, then the string "Hello" is printed.
Now we'll look at how the interactive debugger is used in a mod_perl environment. The Apache::DB module available from CPAN provides a wrapper around perldb for debugging Perl code running under mod_perl.
The server must be run in non-forking (single-process) mode to use the interactive debugger; this mode is turned on by passing the -X flag to the httpd executable. It is convenient to use an IfDefinesection around the Apache::DB configuration; the example below does this using the name PERLDB. With this setup, debugging is turned on only when starting the server with the httpd -X -DPERLDB command.
This configuration section should be placed before any other Perl code is pulled in, so that debugging symbols will be inserted into the syntax tree, triggered by the call to Apache::DB->init. The Apache::DB::handler can be configured using any of the Perl*Handler directives. In this case we use a PerlFixupHandler so handlers in the response phase will bring up the debugger prompt:
<IfDefine PERLDB> <Perl> use Apache::DB ( ); Apache::DB->init; </Perl> <Location /> PerlFixupHandler Apache::DB </Location> </IfDefine>
Since we have used "/" as the argument to the Location directive, the debugger will be invoked for any kind of request, but of course it will immediately quit unless there is some Perl module registered to handle these requests.
In our first example, we will debug the standard Apache::Status module, which is configured like this:
PerlModule Apache::Status <Location /perl-status> SetHandler perl-script PerlHandler Apache::Status </Location>
When the server is started with the debugging flag, a notice will be printed to the console:
panic% ./httpd -X -DPERLDB [notice] Apache::DB initialized in child 950
The debugger prompt will not be available until the first request is made (in our case, to http://localhost/perl-status). Once we are at the prompt, all the standard debugging commands are available. First we run window to get some of the context for the code being debugged, then we move to the next statement after a value has been assigned to $r, and finally we print the request URI. If no breakpoints are set, the continue command will give control back to Apache and the request will finish with the Apache::Status main menu showing in the browser window:
Loading DB routines from perl5db.pl version 1.07 Emacs support available. Enter h or `h h' for help. Apache::Status::handler(.../5.6.1/i386-linux/Apache/Status.pm:55): 55: my($r) = @_; DB<1> w 52 } 53 54 sub handler { 55= => my($r) = @_; 56: Apache->request($r); #for Apache::CGI 57: my $qs = $r->args || ""; 58: my $sub = "status_$qs"; 59: no strict 'refs'; 60 61: if($qs =~ s/^(noh_\w+).*/$1/) { DB<1> n Apache::Status::handler(.../5.6.1/i386-linux/Apache/Status.pm:56): 56: Apache->request($r); # for Apache::CGI DB<1> p $r->uri /perl-status DB<2> c
All the techniques we saw while debugging plain Perl scripts can be applied to this debugging session.
Debugging Apache::Registry scripts is somewhat different, because the handler routine does quite a bit of work before it reaches your script. In this example, we make a request for /perl/test.pl, which consists of the code shown in Example 21-8.
use strict; my $r = shift; $r->send_http_header('text/plain'); print "mod_perl rules";
When a request is issued, the debugger stops at line 28 of Apache/Registry.pm. We set a breakpoint at line 140, which is the line that actually calls the script wrapper subroutine. The continue command will bring us to that line, where we can step into the script handler:
Apache::Registry::handler(.../5.6.1/i386-linux/Apache/Registry.pm:28): 28: my $r = shift; DB<1> b 140 DB<2> c Apache::Registry::handler(.../5.6.1/i386-linux/Apache/Registry.pm:140): 140: eval { &{$cv}($r, @_) } if $r->seqno; DB<2> s Apache::ROOT::perl::test_2epl::handler((eval 87):3): 3: my $r = shift;
Notice the funny package name—it's generated from the URI of the request, for namespace protection. The filename is not displayed, since the code was compiled via eval( ), but the print command can be used to show you $r->filename:
DB<2> n Apache::ROOT::perl::test_2epl::handler((eval 87):4): 4: $r->send_http_header('text/plain'); DB<2> p $r->filename /home/httpd/perl/test.pl
The line number might seem off too, but the window command will give you a better idea of where you are:
DB<4> w 1: package Apache::ROOT::perl::test_2epl;use Apache qw(exit); sub handler { use strict; 2 3: my $r = shift; 4= => $r->send_http_header('text/plain'); 5 6: print "mod_perl rules"; 7 8 } 9 ;
The code from the test.pl file is between lines 2 and 7. The rest is the Apache::Registry magic to cache your code inside a handlersubroutine.
It will always take some practice and patience when putting together debugging strategies that make effective use of the interactive debugger for various situations. Once you have a good strategy, bug squashing can actually be quite a bit of fun!
As we saw earlier, we can use the ptkdb visual debugger to debug CGI scripts running under mod_cgi. At the time of writing it works partially under mod_perl as well. It hangs after the first run, so you have to kill it manually every time. Hopefully it will work completely with mod_perl in the future.
However, ptkdb won't work for mod_perl using the same configuration as used in mod_cgi. We have to tweak the Apache/DB.pm module to use Devel/ptkdb.pm instead of Apache/perl5db.pl.
Open the file in your favorite editor and replace:
require 'Apache/perl5db.pl';
with:
require Devel::ptkdb;
Now when you use the interactive mod_perl debugger configuration from the previous section and issue a request, the ptkdb visual debugger will be loaded.
If you are debugging Apache::Registryscripts, as in the terminal debugging mode example, go to line 140 (or to whatever line number at which the eval { &{$cv}($r, @_) } if $r->seqno;statement is located) and press the step in button to start debugging the script itself.
Note that you can use Apache with ptkdb in plain multi-server mode; you don't have to start httpd with the -X option.
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