HTML::Mason::Devel - Mason Developer's Manual |
HTML::Mason::Devel - Mason Developer's Manual
This manual is written for content developers who know HTML and at least a little Perl. The goal is to write, run, and debug Mason components.
If you are the webmaster (or otherwise responsible for the Mason installation), you should also read the administrator's manual. There you will find information about site configuration, performance tuning, component caching, and so on.
If you are a developer just interested in knowing more about Mason's capabilities and implementation, then the administrator's manual is for you too.
We strongly suggest that you have a working Mason to play with as you
work through these examples. Other component examples can be found in
the samples/
directory.
While Mason can be used for tasks besides implementing a dynamic web site, that is what most people want to do with Mason, and is thus the focus of this manual.
If you are planning to use Mason outside of the web, this manual will still be useful, of course. Also make sure to read the running outside of mod_perl section of the administrator's manual.
If you are just learning Mason and want to get started quickly, we recommend the following sections:
o Initialization and Cleanup (mainly <%init>
)
The component - a mix of Perl and HTML - is Mason's basic building block and computational unit. Under Mason, web pages are formed by combining the output from multiple components. An article page for a news publication, for example, might call separate components for the company masthead, ad banner, left table of contents, and article body. Consider this layout sketch:
+---------+------------------+ |Masthead | Banner Ad | +---------+------------------+ | | | |+-------+|Text of Article ..| || || | ||Related||Text of Article ..| ||Stories|| | || ||Text of Article ..| |+-------+| | | +------------------+ | | Footer | +---------+------------------+
The top level component decides the overall page layout, perhaps with HTML tables. Individual cells are then filled by the output of subordinate components, one for the Masthead, one for the Footer, etc. In practice pages are built up from as few as one, to as many as twenty or more components.
This component approach reaps many benefits in a web environment. The first benefit is consistency: by embedding standard design elements in components, you ensure a consistent look and make it possible to update the entire site with just a few edits. The second benefit is concurrency: in a multi-person environment, one person can edit the masthead while another edits the table of contents. A last benefit is reuseability: a component produced for one site might be useful on another. You can develop a library of generally useful components to employ on your sites and to share with others.
Most components emit chunks of HTML. ``Top level'' components, invoked from a URL, represent an entire web page. Other, subordinate components emit smaller bits of HTML destined for inclusion in top level components.
Components receive form and query data from HTTP requests. When called from another component, they can accept arbitrary parameter lists just like a subroutine, and optionally return values. This enables a type of component that does not print any HTML, but simply serves as a function, computing and returning a result.
Mason actually compiles components down to Perl subroutines, so you can debug and profile component-based web pages with standard Perl tools that understand the subroutine concept, e.g. you can use the Perl debugger to step through components, and Devel::DProf to profile their performance.
Here is a simple component example:
<%perl> my $noun = 'World'; my @time = localtime; </%perl> Hello <% $noun %>, % if ( $time[2] < 12 ) { good morning. % } else { good afternoon. % }
After 12 pm, the output of this component is:
Hello World, good afternoon.
This short example demonstrates the three primary ``in-line'' Perl
sections. In-line sections are generally embedded within HTML and
execute in the order they appear. Other sections (<%init>
,
<%args>
, etc.) are tied to component events like initialization,
cleanup, and argument definition.
The parsing rules for these Perl sections are as follows:
<%perl>
.. </%perl>
tag. The enclosed text is executed as Perl and the return
value, if any, is discarded.
The <%perl>
tag, like all block tags in Mason, is
case-insensitive. It may appear anywhere in the text, and may span any
number of lines.
% lines
Most useful for conditional and loop structures - if, while, foreach, , etc. - as well as side-effect commands like assignments. To improve readability, always put a space after the '%'. Examples:
o Conditional code
% my $ua = $r->header_in('User-Agent'); % if ($ua =~ /msie/i) { Welcome, Internet Explorer users ... % } elsif ($ua =~ /mozilla/i) { Welcome, Netscape users ... % }
o HTML list formed from array
<ul> % foreach $item (@list) { <li><% $item %></li> % } </ul>
o HTML list formed from hash
<ul> % while (my ($key,$value) = each(%ENV)) { <li> <b><% $key %></b>: <% $value %> </li> % } </ul>
o HTML table formed from list of hashes
<table> % foreach my $h (@loh) { <tr> <td><% $h->{foo} %></td> <td bgcolor=#ee0000><% $h->{bar} %></td> <td><% $h->{baz} %></td> </tr> % } </table>
<% xxx % >>
Most useful for printing out variables, as well as more complex expressions. To improve readability, always separate the tag and expression with spaces. Examples:
Dear <% $name %>: We will come to your house at <% $address %> in the fair city of <% $city %> to deliver your $<% $amount %> dollar prize!
The answer is <% ($y+8) % 2 %>.
You are <% $age < 18 ? 'not' : '' %> permitted to enter this site.
<%perl xxx </%perl> >>
Useful for Perl blocks of more than a few lines.
This section describes the various objects in the Mason universe. If you're just starting out, all you need to worry about initially are the request objects.
Two global per-request objects are available to all components: $r and $m.
$r, the mod_perl request object, provides a Perl API to the current Apache request. It is fully described in Apache.pod. Here is a sampling of methods useful to component developers:
$r->uri # the HTTP request URI $r->header_in(..) # get the named HTTP header line $r->content_type # set or retrieve content-type $r->header_out(..) # set or retrieve an outgoing header
$r->content # don't use this one! (see Tips and Traps)
$m, the Mason request object, provides an analogous API for Mason. Almost all Mason features not activated by syntactic tags are accessed via $m methods. You'll be introduced to these methods throughout this document as they are needed. For a description of all methods see HTML::Mason::Request.
Because these are always set inside components, you should not ever define other variables with the same name, or else your code may fail in strange and mysterious ways.
Mason provides an object API for components, allowing you to query a
component's various asociated files, arguments, etc. For a description
of all methods see
HTML::Mason::Component. Typically you
get a handle on a component object from request methods like <
$m-
current_comp >> and $m->fetch_comp
.
Note that for many basic applications all you'll want to do with components is call them, for which no object method is needed. See next section.
Many system objects share the work of serving requests in Mason: HTML::Mason::Lexer, HTML::Mason::Compiler, HTML::Mason::Interp, HTML::Mason::Resolver, and HTML::Mason::ApacheHandler are examples. The administrator creates these objects and provides parameters that shape Mason's behavior. As a pure component developer you shouldn't need to worry about or access these objects, but occasionally we'll mention a relevant parameter.
Mason pages often are built not from a single component, but from multiple components that call each other in a hierarchical fashion.
To call one component from another, use the <& &> tag:
<& comp_path, [name=>value, ...] &>
name => value
pairs,
e.g. player => 'M. Jordan'
.
comp_path may be a literal string (quotes optional) or a Perl expression
that evaluates to a string. To eliminate the need for quotes in most
cases, Mason employs some magic parsing: If the first character is
one of [\w/_.]
, comp_path is assumed to be a literal
string running up to the first comma or &>. Otherwise, comp_path
is evaluated as an expression.
Here are some examples:
# relative component paths <& topimage &> <& tools/searchbox &>
# absolute component path <& /shared/masthead, color=>'salmon' &>
# this component path MUST have quotes because it contains a comma <& "sugar,eggs", mix=>1 &>
# variable component path <& $comp &>
# variable component and arguments <& $comp, %args &>
# you can use arbitrary expression for component path, but it cannot # begin with a letter or number; delimit with () to remedy this <& (int(rand(2)) ? 'thiscomp' : 'thatcomp'), id=>123 &>
Several request methods also exist for calling components. $m->comp
performs the equivalent action to <& &>:
$m->comp('/shared/masthead', color=>'salmon');
$m->scomp
is like the sprintf version of $m->comp
: it returns
the component output, allowing the caller to examine and modify it
before printing:
my $masthead = $m->scomp('/shared/masthead', color=>'salmon'); $masthead =~ ...; $m->print($masthead);
Components can be used to filter part of the page's content using an extended component syntax.
<&| /path/to/comp &> this is the content </&> <&| comp, arg1 => 'hi' &> filters can take arguments </&> <&| comp &> content can include <% "tags" %> of all kinds </&> <&| comp1 &> nesting is also <&| comp2 &> OK </&> </&> <&| SELF:method1 &> subcomponents can be filters </&>
The filtering component can be called in all the same ways a normal component is called, with arguments and so forth. The only difference between a filtering component and a normal component is that a filtering component is expected to fetch the content by calling $m->content and do something with it.
The ending tag may optionally contain the name of the component, and Mason
will verify that it matches the name in the starting tag. This may
be helpful when the tags are far apart or nested. To avoid
ambiguous situations, this is only allowed when the component name
is an unquoted literal (starting with [\w/_.]
). For anything
more complicated, such as <|& $var &>
or <&| 'name' &>
,
the simple </&>
form must be used.
<&| "outer" &> <&| /inner/comp, arg=>'this' &> <&| .mycomp &> Yada yada yada </& .mycomp > </& /inner/comp > </&>
Here is an example of a component used for localization. Its content
is a series of strings in different languages, and it selects the
correct one based on a global $lang
variable, which could be setup
in a site-level autohandler.
<&| /i18n/itext &> <en>Hello, <% $name %> This is a string in English</en> <de>Schoene Gruesse, <% $name %>, diese Worte sind auf Deutsch</de> <pig>ellohay <% substr($name,2).substr($name,1,1).'ay' %>, isthay isay igpay atinlay</pig> </&>
Here is the /i18n/itext component:
<% $text %>
<%init> # this assumes $lang is a global variable which has been set up earlier. local $_ = $m->content; my ($text) = m{<$lang>(.*?)</$lang>}; </%init>
You can explicitly check whether a component has passed content by
checking the boolean $m->has_content
. This allows you to write
a component that will do different things depending on whether it was
passed content. However, before overloading a component in this way,
consider whether splitting the behavior into two distinct components
would work as well.
If a normal component which does not call $m->content
is called
with content, the content will not be output.
If you wrap a filtering component call around the entire component,
the result will be functionally similar to a <%filter>
section.
See also Filtering.
Internally $m->content
is implemented with a closure containing
the part of the component which is the content. In English, that
means that any mason tags and perl code in the content are evaluated
when $m->content
is called, and $m->content
returns the
text which would have been output by mason. Because the contents are
evaluated at the time that $m->content
is called, one can write
components which act as control structures or which output their
contents multiple times with different values for the variables (can
you say taglibs?).
The tricky part of using filter components as control structures is setting up variables which can be accessed from both the filter component and the content, which is in the component which calls the filter component. The content has access to all variables in the surrounding component, but the filtering component does not. There are two ways to do this: use global variables, or pass a reference to a lexical variable to the filter component.
Here is a simple example using the second method:
% my $var; <ol> <&| list_items , list => \@items, var => \$var &> <li> <% $var %></li> </&> </ol>
list_items component:
<%args> @list $var </%args> % foreach (@list) { % $$var = $_; # $var is a reference <% $m->content %> % }
Using global variables can be somewhat simpler. Below is the same
example, with $var
defined as a global variable. The site
administrator must make sure that $var
is included in Mason's
allow_globals parameter. Local-izing $var
within the filter
component will allow the list_items component to be nested.
<ol> <&| list_items, list => \@items &> <li> <% $var %></li> </&> </ol>
list_items component:
<%args> @list </%args> % foreach (@list) { % local $var = $_; <% $m->content %> % }
Besides remembering to include $var
in allow_globals, the
developers should take care not to use that variable is other places
where it might conflict with usage by the filter component.
Local-izing $var will also provide some protection against using it in
other places.
An even simpler method is to use the $_
variable. It is already
global, and is automatically local-ized by the foreach statement:
<ol> <&| list_items, list => \@items &> <li> <% $_ %> </li> </&> </ol>
list_items component:
<%args> @list </%args> % foreach (@list) { <% $m->content %> % }
So far you have seen components used solely to output HTML. However, components may also be used to return values.
While we will demonstrate how this is done, we strongly encourage you to put code like this in modules instead. There are several reasons why this is a good idea:
With that being said, there are times when you may want to write a component which returns a value.
As an example, you might have a component is_netscape
that analyzes
the user agent to determine whether it is a Netscape browser:
<%init> my $ua = $r->header_in('User-Agent'); return ($ua =~ /Mozilla/i && $ua !~ /MSIE/i) ? 1 : 0; </%init>
Because components are implemented underneath with Perl subroutines,
they can return values and even understand scalar/list
context. e.g. The result of wantarray()
inside a component will reflect
whether the component was called in scalar or list context.
The <& &> notation only calls a component for its side-effect, and
discards its return value, if any. To get at the return value of a
component, use the $m->comp
command:
% if ($m->comp('is_netscape')) { Welcome, Netscape user! % }
Mason adds a return undef
to the bottom of each component to
provide an empty default return value. To return your own value from a
component, you must use an explicit return
statement. You cannot
rely on the usual Perl trick of letting return values ``fall through''.
While it is possible for a component to generate output and return
values, there is very little reason for a component to do both. For
example, it would not be very friendly for is_netscape
to output
``hi Mom'' while it was computing its value, thereby surprising the
if
statement! Conversely, any value returned by an output
generating component would typically be discarded by the <& &> tag
that invoked it.
You may sometimes want to have a component call go through all the steps that the initial component call goes through, such as checking for autohandlers and dhandlers. To do this, you need to execute a subrequest.
A subrequest is simply a Mason Request object and has all of the methods normally associated with one.
To create a subrequest you simply use the $m->make_subrequest
method. This method can take any parameters belonging to
HTML::Mason::Request, such as autoflush or
out_method. Once you have a new request object you simply call its
exec
method to execute it, which takes exactly the same parameters
as the comp
method.
Since subrequests inherit their parent request's parameters, output from a component called via a subrequest goes to the same desintation as output from components called during the parent request. Of course, you can change this.
Here are some examples:
<%perl> my $req = $m->make_subrequest( comp => '/some/comp', args => [ id => 172 ] ); $req->exec; </%perl>
If you want to capture the subrequest's output in a scalar, you can
simply pass an out_method parameter to $m->make_subrequest
:
<%perl> my $buffer; my $req = $m->make_subrequest ( comp => '/some/comp', args => [ id => 172 ], out_method => \$buffer ); $req->exec; </%perl>
Now $buffer
contains all the output from that call to /some/comp.
For convenience, Mason also provides an $m->subexec
method.
This method takes the same arguments as $m->comp
and internally
calls $m->make_subrequest
and then exec
on the created
request, all in one fell swoop. This is useful in cases where you
have no need to override any of the parent request object's
attributes.
By default, output from a subrequest appears inline in the calling component, at the point where it is executed. If you wish to do something else, you will need to explicitly override the subrequest's out_method parameter.
Mason Request objects are only designed to handle a single call to
exec
. If you wish to make multiple subrequests, you must create
a new subrequest object for each one.
The first component invoked for a page (the ``top-level component'') resides within the DocumentRoot and is chosen based on the URL. For example:
http://www.foo.com/mktg/prods.html?id=372
Mason converts this URL to a filename, e.g. /usr/local/www/htdocs/mktg/prods.html. Mason loads and executes that file as a component. In effect, Mason calls
$m->comp('/mktg/prods.html', id=>372)
This component might in turn call other components and execute some Perl code, or it might contain nothing more than static HTML.
What happens when a user requests a component that doesn't exist? In
this case Mason scans backward through the URI, checking each
directory for a component named dhandler (``default handler''). If
found, the dhandler is invoked and is expected to use
$m->dhandler_arg
as the parameter to some
access function, perhaps a database lookup or location in another
filesystem. In a sense, dhandlers are similar in spirit to Perl's
AUTOLOAD feature; they are the ``component of last resort'' when a URL
points to a non-existent component.
Consider the following URL, in which newsfeeds/ exists but not the subdirectory LocalNews nor the component Story1:
http://myserver/newsfeeds/LocalNews/Story1
In this case Mason constructs the following search path:
/newsfeeds/LocalNews/Story1 => no such thing /newsfeeds/LocalNews/dhandler => no such thing /newsfeeds/dhandler => found! (search ends) /dhandler
The found dhandler would read ``LocalNews/Story1'' from
$m->dhandler_arg
and use it as a retrieval key into a
database of stories.
Here's how a simple /newsfeeds/dhandler might look:
<& header &> <b><% $headline %></b><p> <% $body %> <& footer &>
<%init> my $arg = $m->dhandler_arg; # get rest of path my ($section, $story) = split("/", $arg); # split out pieces my $sth = $DBH->prepare (qq{SELECT headline,body FROM news WHERE section = ? AND story = ?); $sth->execute($section, $story); my ($headline, $body) = $sth->fetchrow_array; return 404 if !$headline; # return "not found" if no such story </%init>
By default dhandlers do not get a chance to handle requests to a directory itself (e.g. /newsfeeds). These are automatically deferred to Apache, which generates an index page or a FORBIDDEN error. Often this is desirable, but if necessary the administrator can let in directory requests as well; see the allowing directory requests section of the administrator's manual.
A component or dhandler that does not want to handle a particular
request may defer control to the next dhandler by calling <
$m-
decline >>.
When using dhandlers under mod_perl, you may find that sometimes
Apache will not set a content type for a response. This usually
happens when a dhandler handles a request for a non-existent file or
directory. You can add a <Location>
or <LocationMatch>
block containing a SetType
directive to your Apache config file, or
you can just set the content type dynamically by calling <
$r-
content_type >>.
The administrator can customize the file name used for dhandlers with the dhandler_name parameter.
Autohandlers allow you to grab control and perform some action just before Mason calls the top-level component. This might mean adding a standard header and footer, applying an output filter, or setting up global variables.
Autohandlers are directory based. When Mason determines the top-level
component, it checks that directory and all parent directories for a
component called autohandler. If found, the autohandler is called
first. After performing its actions, the autohandler typically calls
$m->call_next
to transfer control to the original intended
component.
$m->call_next
works just like $m->comp
except that the component path
and arguments are implicit. You can pass additional arguments to
$m->call_next
; these are merged with the original arguments, taking
precedence in case of conflict. This allows you, for example, to
override arguments passed in the URL.
Here is an autohandler that adds a common header and footer to each page underneath its directory:
<html> <head><title>McHuffy Incorporated</title></head> <body style="background-color: pink">
% $m->call_next;
<hr /> Copyright 1999 McHuffy Inc. </body> </html>
Same idea, using components for the header/footer:
<& /shared/header &> % $m->call_next; <& /shared/footer &>
The next autohandler applies a filter to its pages, adding an absolute hostname to relative image URLs:
% $m->call_next;
<%filter> s{(<img[^>]+src=\")/} {$1http://images.mysite.com/}ig; </%filter>
Most of the time autohandler can simply call $m->call_next
without needing to know what the next component is. However, should
you need it, the component object is available from
$m->fetch_next
. This is useful for calling the component manually,
e.g. if you want to suppress some original arguments or if you want to
use $m->scomp
to store and process the output.
What happens if more than one autohandler applies to a page? Prior to
version 0.85, only the most specific autohandler would execute. In
0.85 and beyond each autohandler gets a chance to run. The top-most
autohandler runs first; each $m->call_next
transfers control to the
next autohandler and finally to the originally called component. This
allows you, for example, to combine general site-wide templates and
more specific section-based templates.
Autohandlers can be made even more powerful in conjunction with Mason's object-oriented style features: methods, attributes, and inheritance. In the interest of space these are discussed in a separate section, Object-Oriented Techniques.
The administrator can customize the file name used for autohandlers with the autohandler_name parameter.
dhandlers and autohandlers both provide a way to exert control over a large set of URLs. However, each specializes in a very different application. The key difference is that dhandlers are invoked only when no appropriate component exists, while autohandlers are invoked only in conjunction with a matching component.
As a rule of thumb: use an autohandler when you have a set of components to handle your pages and you want to augment them with a template/filter. Use a dhandler when you want to create a set of ``virtual URLs'' that don't correspond to any actual components, or to provide default behavior for a directory.
dhandlers and autohandlers can even be used in the same directory. For example, you might have a mix of real URLs and virtual URLs to which you would like to apply a common template/filter.
This section describes Mason's facilities for passing parameters to components (either from HTTP requests or component calls) and for accessing parameter values inside components.
Any Perl data type can be passed in a component call:
<& /sales/header, s => 'dog', l => [2, 3, 4], h => {a => 7, b => 8} &>
This command passes a scalar ($s), a list (@l), and a hash (%h). The list and hash must be passed as references, but they will be automatically dereferenced in the called component.
Consider a CGI-style URL with a query string:
http://www.foo.com/mktg/prods.html?str=dog&lst=2&lst=3&lst=4
or an HTTP request with some POST content. Mason automatically parses the GET/POST values and makes them available to the component as parameters.
Component parameters, whether they come from GET/POST or another component, can be accessed in two ways.
1. Declared named arguments: Components can define an
<%args>
section listing argument names, types, and
default values. For example:
<%args> $a @b # a comment %c
# another comment $d => 5 $e => $d*2 @f => ('foo', 'baz') %g => (joe => 1, bob => 2) </%args>
Here, $a, @b, and %c are required arguments; the component generates an error if the caller leaves them unspecified. $d, $e, @f and %g are optional arguments; they are assigned the specified default values if unspecified. All the arguments are available as lexically scoped (``my'') variables in the rest of the component.
Arguments are separated by one or more newlines. Comments may be used at the end of a line or on their own line.
Default expressions are evaluated in top-to-bottom order, and one expression may reference an earlier one (as $e references $d above).
Only valid Perl variable names may be used in <%args>
sections. Parameters with non-valid variable names cannot be
pre-declared and must be fetched manually out of the %ARGS hash (see
below). One common example of undeclarable parameters are the
``button.x/button.y'' parameters sent for a form submit.
2. %ARGS hash: This variable, always available, contains all of the
parameters passed to the component (whether or not they were
declared). It is especially handy for dealing with large numbers of
parameters, dynamically named parameters, or parameters with non-valid
variable names. %ARGS can be used with or without an
<%args>
section, and its contents are unrelated to what you
have declared in <%args>
.
Here's how to pass all of a component's parameters to another component:
<& template, %ARGS &>
The following examples illustrate the different ways to pass and receive parameters.
1. Passing a scalar id with value 5.
In a URL: /my/URL?id=5 In a component call: <& /my/comp, id => 5 &> In the called component, if there is a declared argument named... $id, then $id will equal 5 @id, then @id will equal (5) %id, then an error occurs In addition, $ARGS{id} will equal 5.
2. Passing a list colors with values red, blue, and green.
In a URL: /my/URL?colors=red&colors=blue&colors=green In an component call: <& /my/comp, colors => ['red', 'blue', 'green'] &> In the called component, if there is a declared argument named... $colors, then $colors will equal ['red', 'blue', 'green'] @colors, then @colors will equal ('red', 'blue', 'green') %colors, then an error occurs In addition, $ARGS{colors} will equal ['red', 'blue', 'green'].
3. Passing a hash grades with pairs Alice => 92 and Bob => 87.
In a URL: /my/URL?grades=Alice&grades=92&grades=Bob&grades=87 In an component call: <& /my/comp, grades => {Alice => 92, Bob => 87} &> In the called component, if there is a declared argument named... @grades, then @grades will equal ('Alice', 92, 'Bob', 87) %grades, then %grades will equal (Alice => 92, Bob => 87) In addition, $grade and $ARGS{grades} will equal ['Alice',92,'Bob',87] in the URL case, or {Alice => 92, Bob => 87} in the component call case. (The discrepancy exists because, in a query string, there is no detectable difference between a list or hash.)
If you don't like named parameters, you can pass a traditional list of ordered parameters:
<& /mktg/prods.html', 'dog', [2, 3, 4], {a => 7, b => 8} &>
and access them as usual through Perl's @_ array:
my ($scalar, $listref, $hashref) = @_;
In this case no <%args>
section is necessary.
We generally recommend named parameters for the benefits of
readability, syntax checking, and default value automation. However
using @_
may be convenient for very small components, especially
subcomponents created with <%def>
.
Before Mason 1.21, @_ contained copies of the caller's arguments. In Mason 1.21 and beyond, this unnecessary copying was eliminated and @_ now contains aliases to the caller's arguments, just as with regular Perl subroutines. For example, if a component updates $_[0], the corresponding argument is updated (or an error occurs if it is not updatable).
Most users won't notice this change because <%args>
variables
and the %ARGS
hash always contain copies of arguments.
See perlsub for more information on @_ aliasing.
The following sections contain blocks of Perl to execute at specific times.
This section contains initialization code that executes as soon as the component is called. For example: checking that a user is logged in; selecting rows from a database into a list; parsing the contents of a file into a data structure.
Technically an <%init>
block is equivalent to a <%perl>
block at the beginning of the component. However, there is an
aesthetic advantage of placing this block at the end of the component
rather than the beginning.
We've found that the most readable components (especially for
non-programmers) contain HTML in one continuous block at the top, with
simple substitutions for dynamic elements but no distracting blocks of
Perl code. At the bottom an <%init>
block sets up the substitution
variables. This organization allows non-programmers to work with the
HTML without getting distracted or discouraged by Perl code. For example:
<html> <head><title><% $headline %></title></head> <body> <h2><% $headline %></h2> <p>By <% $author %>, <% $date %></p>
<% $body %>
</body> </html>
<%init> # Fetch article from database my $dbh = DBI::connect ...; my $sth = $dbh->prepare("select * from articles where id = ?"); $sth->execute($article_id); my ($headline, $date, $author, $body) = $sth->fetchrow_array; # Massage the fields $headline = uc($headline); my ($year, $month, $day) = split('-', $date); $date = "$month/$day"; </%init>
<%args> $article_id </%args>
This section contains cleanup code that executes just before the component exits. For example: closing a database connection or closing a file handle.
A << <%cleanup> >> block is equivalent to a <%perl>
block at
the end of the component. This means it will NOT execute if the
component explicitly returns, or if an abort or error occurs in that
component or one of its children. Because of this limitation, and
because Perl is usually so good about cleaning up at the end of a
lexical scope (e.g. component), <%cleanup>
sections are rarely
needed.
If you need code that is guaranteed to run when the component or request exits, consider using a mod_perl cleanup handler, or creating a custom class with a DESTROY method.
This code executes once when the component is loaded. Variables declared in this section can be seen in all of a component's code and persist for the lifetime of the component.
This section is useful for declaring persistent component-scoped lexical variables (especially objects that are expensive to create), declaring subroutines (both named and anonymous), and initializing state.
This code does not run inside a request context. You cannot call
components or access $m
or $r
from this section. Also, do not
attempt to return()
from a <%once>
section; the current
compiler cannot properly handle it.
Normally this code will execute individually from every HTTP child
that uses the component. However, if the component is preloaded, this
code will only execute once in the parent. Unless you have total control
over what components will be preloaded, it is safest to avoid
initializing variables that can't survive a fork(), e.g. DBI handles.
Use code like this to initialize such variables in the <%init>
section:
<%once> my $dbh; # declare but don't assign ... </%once>
<%init> $dbh ||= DBI::connect ... ... </%init>
In addition, using $m
or <$r> in this section will not work in a
preloaded component, because neither of those variable exist when a
component is preloaded.
As with <%once>
, lexical (my
) variables declared in this
section can be seen in all the rest of a component's code: the main
body, subcomponents, and methods. However, unlike <%once>
, the
code runs once per request (whenever the component is used) and its
variables last only until the end of the request.
A <%shared>
section is useful for initializing variables needed in, say, the
main body and one more subcomponents or methods. See Object-Oriented Techniques for an example of usage.
It's important to realize that you do not have access to the %ARGS
hash or variables created via an <%args>
block inside a shared
section. However, you can access arguments via
$m->request_args.
Additionally, you cannot call a components' own methods or
subcomponents from inside a <%shared>
, though you can call
other components.
Avoid using <%shared>
for side-effect code that needs to run at a
predictable time during page generation. You may assume only that
<%shared>
runs just before the first code that needs it and runs at
most once per request.
In the current implementation, the scope sharing is done with
closures, so variables will only be shared if they are visible at
compile-time in the other parts of the component. In addition, you
can't rely on the specific destruction time of the shared variables,
because they may not be destroyed until the first time the <
<%shared
>> section executes in a future request. <%init>
offers a more predictable execution and destruction time.
Currently any component with a <%shared>
section incurs an
extra performance penalty, because Mason must recreate its
anonymous subroutines the first time each new request uses the
component. The exact penalty varies between systems and for most
applications will be unnoticeable. However, one should avoid using
<%shared>
when patently unnecessary, e.g. when an <%init>
would work just as well.
Do not attempt to return()
from a <%shared>
section; the
current compiler cannot properly handle it.
Each instance of this section creates a subcomponent embedded
inside the current component. Inside you may place anything that a
regular component contains, with the exception of <%def>
, <%method>
,
<%once>
, and <%shared>
tags.
The name consists of characters in the set [\w._-]
. To
call a subcomponent simply use its name in <& &> or $m->comp
. A
subcomponent can only be seen from the surrounding component.
If you define a subcomponent with the same name as a file-based component in the current directory, the subcomponent takes precedence. You would need to use an absolute path to call the file-based component. To avoid this situation and for general clarity, we recommend that you pick a unique way to name all of your subcomponents that is unlikely to interfere with file-based components. A commonly accepted practice is to start subcomponent names with ``.''.
While inside a subcomponent, you may use absolute or relative paths to call file-based components and also call any of your ``sibling'' subcomponents.
The lexical scope of a subcomponent is separate from the main
component. However a subcomponent can declare its own <%args>
section
and have relevant values passed in. You can also use a <%shared>
section to declare variables visible from both scopes.
In the following example, we create a ``.link'' subcomponent to produce a standardized hyperlink:
<%def .link> <a href="http://www.<% $site %>.com"><% $label %></a>
<%args> $site $label=>ucfirst($site) </%args> </%def>
Visit these sites: <ul> <li><& .link, site=>'yahoo' &></li> <li><& .link, site=>'cmp', label=>'CMP Media' &></li> <li><& .link, site=>'excite' &></li> </ul>
Each instance of this section creates a method embedded inside the current component. Methods resemble subcomponents in terms of naming, contents, and scope. However, while subcomponents can only be seen from the parent component, methods are meant to be called from other components.
There are two ways to call a method. First, via a path of the form ``comp:method'':
<& /foo/bar:method1 &>
$m->comp('/foo/bar:method1');
Second, via the call_method component method:
my $comp = $m->fetch_comp('/foo/bar'); ... $comp->call_method('method1');
Methods are commonly used in conjunction with autohandlers to make templates more flexible. See Object-Oriented Techniques for more information.
You cannot create a subcomponent and method with the same name. This is mostly to prevent obfuscation and accidental errors.
The <%flags>
and <%attr>
sections consist of key/value
pairs, one per line, joined by '=>'. In each pair, the key must be
any valid Perl ``bareword identifier'' (made of letters, numbers, and
the underscore character), and the value may be any scalar value,
including references. An optional comment may follow each line.
Use this section to set official Mason flags that affect the current component's behavior.
Currently there is only one flag, inherit
, which specifies the
component's parent in the form of a relative or absolute component
path. A component inherits methods and attributes from its parent; see
Object-Oriented Techniques for
examples.
<%flags> inherit=>'/site_handler' </%flags>
Use this section to assign static key/value attributes that can be queried from other components.
<%attr> color => 'blue' fonts => [qw(arial geneva helvetica)] </%attr>
To query an attribute of a component, use the attr
method:
my $color = $comp->attr('color')
where $comp is a component object.
Mason evaluates attribute values once when loading the component. This makes them faster but less flexible than methods.
This section describes several ways to apply filtering functions over the results of the current component. By separating out and hiding a filter that, say, changes HTML in a complex way, we allow non-programmers to work in a cleaner HTML environment.
The <%filter>
section allows you to arbitrarily filter the output of
the current component. Upon entry to this code, $_
contains the
component output, and you are expected to modify it in place. The code
has access to component arguments and can invoke subroutines, call
other components, etc.
This simple filter converts the component output to UPPERCASE:
<%filter> tr/a-z/A-Z/ </%filter>
The following navigation bar uses a filter to ``unlink'' and highlight the item corresponding to the current page:
<a href="/">Home</a> | <a href="/products/">Products</a> | <a href="/bg.html">Background</a> | <a href="/finance/">Financials</a> | <a href="/support/">Tech Support</a> | <a href="/contact.html">Contact Us</a>
<%filter> my $uri = $r->uri; s{<a href="$uri/?">(.*?)</a>} {<b>$1</b>}i; </%filter>
This allows a designer to code such a navigation bar intuitively
without if
statements surrounding each link! Note that the regular
expression need not be very robust as long as you have control over what
will appear in the body.
A filter block does not have access to variables declared in a
component's <%init>
section, though variables declared in the
<%args>
, <%once>
or <%shared>
blocks are
usable in a filter.
It should be noted that a filter cannot rely on receiving all of a
component's output at once, and so may be called multiple times with
different chunks of output. This can happen if autoflush is on, or if
a filter-containing component, or the components it calls, call the
$m->flush_buffer()
method.
You should never call Perl's return()
function inside a filter
section, or you will not see any output at all.
You can use Component Calls with Content if you want to filter specific parts of a component rather than the entire component.
There are several ways to place comments in components, i.e. arbitrary text that is ignored by the parser.
Text in this section is treated as a comment and ignored. Most useful
for a component's main documentation. One can easily write a program
to sift through a set of components and pull out their <%doc>
blocks to form a reference page.
A <% %>
tag is considered a comment if all of its lines are
either whitespace, or begin with a '#' optionally preceded by
whitespace. For example,
<% # This is a single-line comment %>
<% # This is a # multi-line comment %>
Because a line beginning with %
is treated as Perl, %#
automatically works as a comment. However we prefer the <% #
comment %>
form over %#
, because it stands out a little more
as a comment and because it is more flexible with regards to preceding
whitespace.
Anything between these two lines
% if (0) { ... % }
will be skipped by Mason, including component calls. While we don't recomend this for comments per se, it is a useful notation for ``commenting out'' code that you don't want to run.
HTML and other markup languages will have their own comment markers, for example
<!-- -->
. Note two important differences with these comments versus the
above comments:
<!-- Oops, the code below will still run <& /shared/expensive.mhtml &> -->
Text in this section is printed as-is with all Mason syntax ignored. This is useful, for example, when documenting Mason itself from a component:
<%text> % This is an example of a Perl line. <% This is an example of an expression block. %> </%text>
This works for almost everything, but doesn't let you output
</%text>
itself! When all else fails, use $m->print
:
% $m->print('The tags are <%text> and </%text>.');
Mason has facilities for escaping the output from <% %>
tags, on either a site-wide or a per-expression basis.
Any <% %>
expression may be terminated by a '|' and one or more
escape flags (plus arbitrary whitespace), separated by commas:
<% $file_data |h %>
The current valid flags are:
HTML::Entities::encode()
.
Before Perl 5.8.0 this module assumes that text is in the ISO-8859-1
character set; see the next section for how to override this escaping. After 5.8.0, the encoding
assumes that text is in Unicode.
The administrator may specify a set of default escape flags via the
default_escape_flags parameter. For example, if the administrator
sets default_escape_flags to ['h']
, then all <% %> expressions
will automatically be HTML-escaped. In this case you would use the
n
flag to turn off HTML-escaping for a specific expression:
<% $html_block |n %>
Multiple escapes can be specified as a comma-separated list:
<% $uri | u, n %>
The old pre-defined escapes, 'h', 'u', and 'n', can be used without commas, so that this is legal:
<% $uri | un %>
However, this only works for these three escapes, and no others. If you are using user-defined escapes as well, you must use a comma:
<% $uri | u, add_session %>
Besides the default escapes mentioned above, it is possible for the user to define their own escapes or to override the built-in 'h' and 'u' escapes.
This is done via the Interp object's escape_flags parameter or
set_escape() method. Escape
names may be any number of characters as long as it matches the regex
/^[\w-]+$/
. The one exception is that you cannot override the 'n'
flag.
Each escape flag is associated with a subroutine reference. The subroutine should expect to receive a scalar reference, which should be manipulated in place. Any return value from this subroutine is ignored.
Escapes can be defined at any time but using an escape that is not defined will cause an error when executing that component.
A common use for this feature is to override the built-in HTML
escaping, which will not work with non-ISO-8559-1 encodings. If
you are using such an encoding and want to switch the 'h' flag to do
escape just the minimal set of characters (<
, >
, &
,
"
), put this in your Apache configuration:
PerlSetVar MasonEscapeFlags "h => \&HTML::Mason::Escapes::basic_html_escape"
Or, in a top-level autohandler:
$m->interp->set_escape( h => \&HTML::Mason::Escapes::basic_html_escape );
Or you could write your own escape function for a particular encoding:
$ah->interp->set_escape( h => \&my_html_escape );
And of course this can be used for all sorts of other things, like a naughty words filter for the easily offended:
$interp->set_escape( 'no-naughty' => \&remove_naughty_words );
You can manually apply one or more escapes to text using the Interp object's apply_escapes()
method. e.g.
$m->interp->apply_escapes( 'some html content', 'h' );
A backslash (\) at the end of a line suppresses the newline. In HTML
components, this is mostly useful for fixed width areas like <pre>
tags, since browsers ignore white space for the most part. An example:
<pre> foo % if (1) { bar % } baz </pre>
outputs
foo bar baz
because of the newlines on lines 2 and 4. (Lines 3 and 5 do not generate a newline because the entire line is taken by Perl.) To suppress the newlines:
<pre> foo\ % if (1) { bar\ % } baz </pre>
which prints
foobarbaz
Mason's data caching interface allows components to cache the results of computation for improved performance. Anything may be cached, from a block of HTML to a complex data structure.
Each component gets its own private, persistent data cache. Except under special circumstances, one component does not access another component's cache. Each cached value may be set to expire at a certain time.
Data caching is implemented on top of one of two external caching
APIs: Cache::Cache
or its newer sibling CHI
. You control which
one Mason uses with the data_cache_api parameter. Currently
Cache::Cache
is the default, but we will switch to CHI
once it
is more mature. The APIs are very similar for Mason users, so that
most of the information below applies to both; any differences are
noted.
The $m->cache
method returns a cache object representing the cache for
this component. Here's the typical usage of $m->cache
:
my $result = $m->cache->get('key'); if (!defined($result)) { ... compute $result ... $m->cache->set('key', $result); }
$m->cache->get
attempts to retrieve this component's cache
value. If the value is available it is placed in $result
. If the
value is not available, $result
is computed and stored in the
cache by $m->cache->set
.
A cache can store multiple key/value pairs. A value can be
anything serializable by Storable
, from a simple scalar to an
arbitrary complex list or hash reference:
$m->cache->set(name => $string); $m->cache->set(friends => \@list); $m->cache->set(map => \%hash);
You can fetch all the keys in a cache with
my @idents = $m->cache->get_keys;
It should be noted that Mason reserves all keys beginning with
__mason
for its own use.
You can pass an optional third argument to $m->cache->set
indicating when the item should expire:
$m->cache->set('name1', $string1, '5 min'); # Expire in 5 minutes $m->cache->set('name2', $string2, '3h'); # Expire in 3 hours
To change the expiration time for a piece of data, call set
again
with the new expiration. To expire an item immediately, use
$m->cache->remove
.
You can also specify an expiration condition when you fetch the item, using the expire_if option:
my $result = $m->cache->get('key', expire_if=>sub { $_[0]->get_created_at < (stat($file))[9] });
expire_if takes an anonymous subroutine, which is called with the cache object as its only parameter. If the subroutine returns a true value, the item is expired. In the example above, we expire the item whenever a certain file changes.
Finally, you can expire a cache item from an external script; see Accessing a Cache Externally below.
The code shown in ``Basic Usage'' above,
my $result = $m->cache->get('key'); if (!defined($result)) { ... compute $result ... $m->cache->set('key', $result); }
can suffer from a kind of race condition for caches that are accessed frequently and take a long time to recompute.
Suppose that a particular cache value is accessed five times a second and takes three seconds to recompute. When the cache expires, the first process comes in, sees that it is expired, and starts to recompute the value. The second process comes in and does the same thing. This sequence continues until the first process finishes and stores the new value. On average, the value will be recomputed and written to the cache 15 times!
One solution is the busy_lock flag:
my $result = $m->cache->get('key', busy_lock=>'30 sec');
In this case, when the value cannot be retrieved, get()
sets
the expiration time of the value 30 seconds in the future before
returning undef
. This tells the first process to compute the new
value while causing subsequent processes to use the old value for 30
seconds.
Should the 30 seconds expire before the first process is done, a second process will start computing the new value while setting the expiration time yet another 30 seconds in the future, and so on.
The disadvantage of this solution is that multiple writes to the cache
will be performed for each set()
.
Another solution, available only if you are using CHI
, is
expires_variance
which will create a variable time window during
which expiration may occur. See the CHI
documentation for details.
Occasionally you will need to cache the complete output of a
component. For this purpose, Mason offers the $m->cache_self
method. This method causes Mason to check to see if this component
has already been run and its output cached. If this is the case, this
output is simply sent as output. Otherwise, the component run
normally and its output and return value cached.
It is typically used right at the top of an <%init>
section:
<%init> return if $m->cache_self(key => 'fookey', expires_in => '3 hours', ... <other cache options> ...); ... <rest of init> ... </%init>
A full list of parameters and examples are available in the cache_self section of the Request manual.
$m->cache->get_object
returns a Cache::Object
or
CHI::CacheObject
associated with a particular key. You can use this
to retrieve useful meta-data:
my $co = $m->cache->get_object('name1'); $co->get_created_at(); # when was object stored in cache $co->get_expires_at(); # when does object expire
The Cache::Cache
API is implemented by a variety of backend subclasses. For
example, FileCache
implements the interface with a set of
directories and files, MemoryCache
implements the interface in
process memory, and SharedMemoryCache
implements the interface in
shared memory.
By default $m->cache
uses FileCache
, but you can override
this with the cache_class keyword. The value must be the name of a
Cache::Cache
subclass; the prefix ``Cache::'' need not be included.
For example:
my $result = $m->cache(cache_class => 'MemoryCache')->get('key'); $m->cache(cache_class => 'MemoryCache')->set(key => $result);
You can even specify different subclasses for different keys in the
same component. Just make sure the correct value is passed to all
calls to $m->cache
; Mason does not remember which subclass you
have used for a given component or key.
The administrator can set the default cache subclass used by all components with the data_cache_defaults parameter.
The CHI
API is implemented by a variety of drivers, for example
CHI::Driver::File
, CHI::Driver::FastMmap
, and
CHI::Driver::Memcached
.
CHI::Driver::File
is the default, but you can override this with
the driver keyword. The value must be the name of a CHI::Driver
subclass; the prefix ``CHI::Driver::'' need not be included. For
example:
my $cache = $m->cache(driver => 'Memcached', servers => [ ... ]); my $result = $cache->get('key'); $cache->set(key => $result);
You can even specify different subclasses for different keys in the
same component. Just make sure the correct value is passed to all
calls to $m->cache
; Mason does not remember which subclass you
have used for a given component or key.
The administrator can set the default cache subclass used by all components with the data_cache_defaults parameter.
To access a component's cache from outside the component (e.g. in an external Perl script), you'll need have the following information:
Cache::Cache
, the function
HTML::Mason::Utils::data_cache_namespace
,
given a component id (usually just the component path), returns the
namespace. For CHI
, the component id/path itself is the namespace.
the cache_root, for file-based caches only. Defaults to the
``cache'' subdirectory under the Mason data directory.
Given this information you can get a handle on the component's cache. For example, the following code removes a cache item for component /foo/bar, assuming the data directory is /usr/local/www/mason and you are using the default file backend:
use HTML::Mason::Utils qw(data_cache_namespace);
# With Cache::Cache my $cache = new Cache::FileCache ( { namespace => data_cache_namespace("/foo/bar"), cache_root => "/usr/local/www/mason/cache" } );
# With CHI my $cache = CHI->new ( driver => 'File', namespace => "/foo/bar", cache_root => "/usr/local/www/mason/cache" );
# Remove one key $cache->remove('key1');
# Remove all keys $cache->clear;
For users upgrading from 1.0x and earlier, any existing $m->cache
code will be incompatible with the new API. However, if you wish to
continue using the 1.0x cache API for a while, you (or your
administrator) can set data_cache_api to '1.0'. All of the
$m->cache options with the exception of tie_class
should be
supported.
The access_data_cache
function is no longer available; this will
need to be converted to use Cache::Cache
directly, as described in
the previous section.
Mason automatically sends HTTP headers via $r->send_http_header
but it will not send headers if they've already been sent manually.
To determine the exact header behavior on your system, you need to know whether your server's default is to have autoflush on or off. Your administrator should have this information. If your administrator doesn't know then it is probably off, the default.
With autoflush off the header situation is extremely simple: Mason waits until the very end of the request to send headers. Any component can modify or augment the headers.
With autoflush on the header situation is more complex. Mason will
send headers just before sending the first output. This means that if
you want to affect the headers with autoflush on, you must do so
before any component sends any output. Generally this takes place in
an <%init>
section.
For example, the following top-level component calls another component to see whether the user has a cookie; if not, it inserts a new cookie into the header.
<%init> my $cookie = $m->comp('/shared/get_user_cookie'); if (!$cookie) { $cookie = new CGI::Cookie (...); $r->header_out('Set-cookie' => $cookie); } ... </%init>
With autoflush off this code will always work. Turn autoflush on and this code will only work as long as /shared/get_user_cookie doesn't output anything (given its functional nature, it shouldn't).
The administrator can turn off automatic header sending via the auto_send_headers parameter. You can also turn it off on individual pages with
$m->auto_send_headers(0);
The value returned from the top-most component becomes the status code of the request. If no value is explicitly returned, it defaults to OK (0).
Simply returning an error status (such as 404) from the top-most component has two problems in practice. First, the decision to return an error status often resides further down in the component stack. Second, you may have generated some content by the time this decision is made. (Both of these are more likely to be true when using autohandlers.)
Thus the safer way to generate an error status is
$m->clear_buffer; $m->abort($status);
$m->abort
bypasses the component stack and ensures that
$status
is returned from the top-most component. It works by
throwing an exception. If you wrapped this code (directly or
indirectly) in an eval, you must take care to rethrow the exception,
or the status will not make it out:
eval { $m->comp('...') }; if (my $err = $@) { if ($m->aborted) { die $err; } else { # deal with non-abort exceptions } }
A filter section will still be called after a component aborts with
$m->abort
. You can always check $m->aborted
in your
<%filter>
block if you don't want to run the filter after an abort.
<%filter> unless ( $m->aborted ) { $_ .= ' filter stuff'; } </%filter>
Because it is so commonly needed, Mason 1.1x and on provides an external redirect method:
$m->redirect($url); # Redirects with 302 status
This method uses the clear_buffer/abort technique mentioned above, so the same warnings apply regarding evals.
Also, if you generate any output after calling $m->redirect
,
then this output will be sent, and will break the redirect. For
example:
% eval { $m->comp('redirect', ...) };
% die $@ if $@;
The blank line between the two Perl lines is new output generated
after the redirect. Either remove it or call $m->clear_buffer
immediately before calling die()
.
There are two ways to perform redirects that are invisible to the client.
First, you can use a Mason subrequest (see Subrequests). This only works if you are redirecting to another Mason page.
Second, you can use Apache's internal_redirect method, which works whether or not the new URL will be handled by Mason. Use it this way:
$r->internal_redirect($url); $m->auto_send_headers(0); $m->clear_buffer; $m->abort;
The last three lines prevent the original request from accidentally generating extra headers or content.
You can use the perl debugger in conjunction with a live mod_perl/Mason server with the help of Apache::DB, available from CPAN. Refer to the Apache::DB documentation for details.
The only tricky thing about debugging Mason pages is that components
are implemented by anonymous subroutines, which are not easily
breakpoint'able. To remedy this, Mason calls the dummy subroutine
debug_hook
at the beginning of each component. You can breakpoint
this subroutine like so:
b HTML::Mason::Request::debug_hook
debug_hook is called with two parameters: the current Request object and the full component path. Thus you can breakpoint specific components using a conditional on $_[1]:
b HTML::Mason::Request::debug_hook $_[1] =~ /component name/
You can avoid all that typing by adding the following to your ~/.perldb file:
# Perl debugger aliases for Mason $DB::alias{mb} = 's/^mb\b/b HTML::Mason::Request::debug_hook/';
which reduces the previous examples to just:
mb mb $_[1] =~ /component name/
Mason normally inserts '#line' directives into compiled components so that line numbers are reported relative to the source file. Depending on your task, this can be a help or a hindrance when using the debugger. The administrator can turn off '#line' directives with the use_source_line_numbers parameter.
Earlier you learned how to assign a common template to an entire hierarchy of pages using autohandlers. The basic template looks like:
header HTML % $m->call_next; footer HTML
However, sometimes you'll want a more flexible template that adjusts to the requested page. You might want to allow each page or subsection to specify a title, background color, or logo image while leaving the rest of the template intact. You might want some pages or subsections to use a different template, or to ignore templates entirely.
These issues can be addressed with the object-oriented style primitives introduced in Mason 0.85.
Note: we use the term object-oriented loosely. Mason borrows concepts like inheritance, methods, and attributes from object methodology but implements them in a shallow way to solve a particular set of problems. Future redesigns may incorporate a deeper object architecture if the current prototype proves successful.
Every component may have a single parent. The default parent is a
component named autohandler
in the closest parent directory. This
rule applies to autohandlers too: an autohandler may not have itself
as a parent but may have an autohandler further up the tree as its
parent.
You can use the inherit
flag to override a component's parent:
<%flags> inherit => '/foo/bar' </%flags>
If you specify undef as the parent, then the component inherits from no one. This is how to suppress templates.
Currently there is no way to specify a parent dynamically at run-time, or to specify multiple parents.
At page execution time, Mason builds a chain of components from the
called component, its parent, its parent's parent, and so
on. Execution begins with the top-most component; calling
$m->call_next
passes control to the next component in the chain. This
is the familiar autohandler ``wrapping'' behavior, generalized for any
number of arbitrarily named templates.
A template can access methods and/or attributes of the requested
page. First, use $m->request_comp
to get a handle on the
appropriate component:
my $self = $m->request_comp;
$self now refers to the component corresponding to the requested page (the component at the end of the chain).
To access a method for the page, use call_method
:
$self->call_method('header');
This looks for a method named 'header' in the page component. If no such method exists, the chain of parents is searched upwards, until ultimately a ``method not found'' error occurs. Use 'method_exists' to avoid this error for questionable method calls:
if ($self->method_exists('header')) { ...
The component returned by the $m->request_comp
method never
changes during request execution. In contrast, the component returned
by $m->base_comp
may change several times during request
execution.
When execution starts, the base component is the same as the requested component. Whenever a component call is executed, the base component may become the component that was called. The base component will change for all component calls except in the following cases:
<& $m->fetch_comp('/some/comp'), foo => 1 &>A subcomponent (defined with
<%def>
) is called.
A method is called via the use of SELF:
, PARENT:
, or
REQUEST:
. These are covered in more detail below.
In all other cases, the base component is the called component or the called component's owner component if that called component is a method.
As hinted at above, Mason provides a shortcut syntax for method calls.
If a component call path starts with SELF:
, then Mason will start
looking for the method (the portion of the call after SELF:
), in
the base component.
<& SELF:header &> $m->comp('SELF:header')
If the call path starts with PARENT:
, then Mason will start looking
in the current component's parent for the named method.
<& PARENT:header &> $m->comp('PARENT:header')
In the context of a component path, PARENT is shorthand for
$m->current_comp->parent
.
If the call path begins with REQUEST:
, then Mason looks for the
method in the requested component. REQUEST is shorthand for <
$m-
request_comp >>.
The rules for attributes are similar. To access an attribute for the
page, use attr
:
my $color = $self->attr('color')
This looks for an attribute named 'color' in the $self component. If
no such attribute exists, the chain of parents is searched upwards,
until ultimately an ``attribute not found'' error occurs. Use
attr_exists
or attr_if_exist
to avoid this error for
questionable attributes:
if ($self->attr_exists('color')) { ...
my $color = $self->attr_if_exists('color'); # if it doesn't exist $color is undef
A component's main body and its methods occupy separate lexical
scopes. Variables declared, say, in the <%init>
section of the main
component cannot be seen from methods.
To share variables, declare them either in the <%once>
or <%shared>
section. Both sections have an all-inclusive scope. The <%once>
section runs once when the component loads; its variables are
persistent for the lifetime of the component. The <%shared>
section
runs once per request (when needed), just before any code in the
component runs; its variables last only til the end of the request.
In the following example, various sections of code require information
about the logged-in user. We use a <%shared>
section to fetch these
in a single request.
<%attr> title=>sub { "Account for $full_name" } </%attr>
<%method lefttoc> <i><% $full_name %></i> (<a href="logout.html">Log out</a>)<br /> ... </%method>
Welcome, <% $fname %>. Here are your options:
<%shared> my $dbh = DBI::connect ...; my $user = $r->connection->user; my $sth = $dbh->prepare("select lname,fname, from users where user_id = ?"); $sth->execute($user); my ($lname, $fname) = $sth->fetchrow_array; my $full_name = "$first $last"; </%shared>
<%shared>
presents a good alternative to <%init>
when data is needed
across multiple scopes. Outside these situations, <%init>
is preferred
for its slightly greater speed and predictable execution model.
Let's say we have three components:
/autohandler /products/autohandler /products/index.html
and that a request comes in for /products/index.html.
/autohandler contains a general template for the site, referring to a number of standard methods and attributes for each page:
<head> <title><& SELF:title &></title> </head> <body style="<% $self->attr('body_style') %>"> <& SELF:header &>
<div id="main"> % $m->call_next; </div>
<& SELF:footer &> </body>
<%init> my $self = $m->base_comp; ... </%init>
<%attr> body_style => 'standard' </%attr>
<%method title> McGuffey Inc. </%method>
<%method header> <h2><& SELF:title &></h2> </%method>
<%method footer> </%method>
Notice how we provide defaults for each method and attribute, even if blank.
/products/autohandler overrides some attributes and methods for the /products section of the site.
<%attr> body_style => 'plain' </%attr> <%method title> McGuffey Inc.: Products </%method>
% $m->call_next;
Note that this component, though it only defines attributes and
methods, must call $m->call_next
if it wants the rest of the
chain to run.
/products/index.html might override a few attributes, but mainly provides a primary section for the body.
$r->content
itself to read request input, emptying
the input buffer and leaving a trap for the unwary: subsequent calls
to $r->content
hang the server. This is a mod_perl ``feature'' that
may be fixed in an upcoming release.
For the same reason you should not create a CGI object like
my $query = new CGI;
when handling a POST; the CGI module will try to reread request input and hang. Instead, create an empty object:
my $query = new CGI ("");
such an object can still be used for all of CGI's useful HTML output functions. Or, if you really want to use CGI's input functions, initialize the object from %ARGS:
my $query = new CGI (\%ARGS);
Modules which work as source filters, such as Switch.pm
, will only
work when you are using object files. This is because of how source
filters are implemented, and cannot be changed by the Mason authors.
Jonathan Swartz <swartz@pobox.com>, Dave Rolsky <autarch@urth.org>, Ken Williams <ken@mathforum.org>
HTML::Mason, HTML::Mason::Admin, HTML::Mason::Request
HTML::Mason::Devel - Mason Developer's Manual |