What's the difference between 'my' and 'our' in Raku?
The my
scope declarator implies lexical scoping: following its declaration, the symbol is visible to the code within the current set of curly braces. We thus tend to call the region within a pair of curly braces a "lexical scope". For example:
sub foo($p) {
# say $var; # Would be a compile time error, it's not declared yet
my $var = 1;
if $p {
$var += 41; # Inner scope, $var is visible
}
return $var; # Same scope that it was declared in, $var is visible
}
# say $var; # $var is no longer available, the scope ended
Since the variable's visibility is directly associated with its location in the code, lexical scope is really helpful in being able to reason about programs. This is true for:
- The programmer (both for their own reasoning about the program, but also because more errors can be detected and reported when things have lexical scope)
- The compiler (lexical scoping permits easier and better optimization)
- Tools such as IDEs (analyzing and reasoning about things with lexical scope is vastly more tractable)
Early on in the design process of the language that would become Raku, subroutines did not default to having lexical scope (and had our
scope like in Perl), however it was realized that lexical scope is a better default. Making subroutine calls always try to resolve a symbol with lexical scope meant it was possible to report undeclared subroutines at compile time. Furthermore, the set of symbols in lexical scope is fixed at compile time, and in the case of declarative constructs like subroutines, the routine is bound to that symbol in a readonly manner. This also allows things like compile-time resolution of multiple dispatch, compile-time argument checking, and so forth. It is likely that future versions of the Raku language will specify an increasing number of compile-time checks on lexically scoped program elements.
So if lexical scoping is so good, why does our
(also known as package) scope exist? In short, because:
- Sometimes we want to share things more widely than within a given lexical scope. We could just declare everything lexical and then mark things we want to share with
is export
, but.. - Once we get to the point of using a lot of different libraries, having everything try to export things into the single lexical scope of the consumer would likely lead to a lot of conflicts
Packages allow namespacing of symbols. For example, if I want to use the Cro clients for both HTTP and WebSockets in the same code, I can happily use both, and refer to them as Cro::HTTP::Client
and Cro::WebSocket::Client
respectively.
Packages are introduced by package declarators, such as class
, module
, grammar
, and (with caveats) role
. An our
declaration will make an installation in the enclosing package construct.
These packages ultimately exist within a top-level package named GLOBAL
- which is fitting, since they are effectively globally visible. If we declare an our
-scoped variable, it is thus a global variable (albeit hopefully a namespaced one), about which enough has been written that we know we should pause for thought and wonder if a global variable is the best API decision (because, ultimately, everything that ends up visible via GLOBAL
is an API decision).
Where things do get a bit blurry, however, is that we can have lexical packages. These are packages that do not get installed in GLOBAL
. I find these extremely useful when doing OO programming. For example, I might have:
# This class that ends up in GLOBAL...
class Cro::HTTP::Client {
# Lexically scoped classes, which are marked `my` and thus hidden
# implementation details. This means I can refactor them however I
# want, and never have to worry about downstream fallout!
my class HTTP1Pipeline {
# Implementation...
}
my class HTTP2Pipeline {
# Implementation...
}
# Implementation...
}
Lexical packages can also be nested and contain our
-scoped variables, however don't end up being globally visible (unless we somehow choose to leak them out).
Different Raku program elements have been ascribed a default scope:
- Subroutines default to lexical (
my
) scope - Methods default to
has
scope (only visible through a method dispatch) - Type (class, role, grammar, subset) and module declarations default to package (
our
) scope - Constants and enumerations default to package (
our
) scope
Effectively, things that are most often there to be shared default to package scope, and the rest do not. (Variables do force us to pick a scope explicitly, however the most common choice is also the shortest one to type.)
Personally, I'm hesitant to make a thing more visible than the language defaults, however I'll often make them less visible (for example, my
on constants that are for internal use, and on classes that I'm using to structure implementation details). When I could do something by exposing an our
-scoped variable in a globally visible package, I'll still often prefer to make it my
-scoped and provide a sub
(exported) or method
(visible by virtue of being on a package-scoped class
) to control access to it, to buy myself some flexibility in the future. I figure it's OK to make wrong choices now if I've given myself space to make them righter in the future without inconveniencing anyone. :-)
In summary:
- Use
my
scope for everything that's an implementation detail - Also use
my
scope for things that you plan toexport
, but remember exporting puts symbols into the single lexical scope of the consumer and risks name clashes, so be thoughtful about exporting particularly generic names - Use
our
for things that are there to be shared, and when its desired to use namespacing to avoid clashes - The elements we'd most want to share default to
our
scope anyway, so explicitly writingour
should give pause for thought
The my
vs our
distinction is mainly relevant when generating the symbol table. For example:
my $a; # Create symbol <$a> at top level
package Foo { # Create symbol <Foo> at top level
my $b; # Create symbol <$b> in Foo scope
our $c; # Create symbol <$c> in Foo scope
} # and <Foo::<$c>> at top level
In practice this means that anything that is our
scoped is readily shared to the outside world by prefixing the package identifier ($Foo::c
or Foo::<$c>
are synonymous), and anything that is my
scoped is not readily available — although you can certainly provide access to it via, e.g., getter subs.
Most of the time you'll want to use my
. Most variables just belong to their current scope, and no one has any business peaking in. But our
can be useful in some cases:
- constants that don't poison the symbol table (this is why, actually, using
constant
implies anour
scope). So you can make a more C-style enum/constants by usingpackage Colors { constant red = 1; constant blue = 2; }
and then referencing them asColors::red
- classes or subs that should be accessible but needn't be exported (or shouldn't be because overlapping symbols with builtins or other modules). Exporting symbols can be great, but sometimes it's also nice to have the package/module namespace to remind you what stuff goes with. As such, it's also a nice way to manage options at runtime via subs:
CoolModule::set-preferences( ... )
. (although dynamic variables can be used to nice effect here as well).
I'm sure others will comment with other times the our
scope is useful, but these are the ones from my own experience.