44 KiB
Modules
Modules let you organize Racket code into multiple files and reusable libraries.
1 Module Basics
1.1 Organizing Modules
1.2 Library Collections
1.3 Packages and Collections
1.4 Adding Collections
2 Module Syntax
2.1 The `module` Form
2.2 The `#lang` Shorthand
2.3 Submodules
2.4 Main and Test Submodules
3 Module Paths
4 Imports: `require`
5 Exports: `provide`
6 Assignment and Redefinition
7 Modules and Macros
1. Module Basics
Each Racket module typically resides in its own file. For example,
suppose the file "cake.rkt"
contains the following module:
"cake.rkt"
#lang racket
(provide print-cake)
; draws a cake with n candles
(define (print-cake n)
(show " ~a " n #\.)
(show " .-~a-. " n #\|)
(show " | ~a | " n #\space)
(show "---~a---" n #\-))
(define (show fmt n ch)
(printf fmt (make-string n ch))
(newline))
Then, other modules can import "cake.rkt"
to use the print-cake
function, since the provide
line in "cake.rkt"
explicitly exports
the definition print-cake
. The show
function is private to
"cake.rkt"
i.e., it cannot be used from other modules
, since
show
is not exported.
The following "random-cake.rkt"
module imports "cake.rkt"
:
"random-cake.rkt"
#lang racket
(require "cake.rkt")
(print-cake (random 30))
The relative reference "cake.rkt"
in the import (require "cake.rkt")
works if the "cake.rkt"
and "random-cake.rkt"
modules are in the
same directory. Unix-style relative paths are used for relative module
references on all platforms, much like relative URLs in HTML pages.
1.1. Organizing Modules
The "cake.rkt"
and "random-cake.rkt"
example demonstrates the most
common way to organize a program into modules: put all module files in a
single directory perhaps with subdirectories
, and then have the
modules reference each other through relative paths. A directory of
modules can act as a project, since it can be moved around on the
filesystem or copied to other machines, and relative paths preserve the
connections among modules.
As another example, if you are building a candy-sorting program, you
might have a main "sort.rkt"
module that uses other modules to access
a candy database and a control sorting machine. If the candy-database
module itself is organized into sub-modules that handle barcode and
manufacturer information, then the database module could be
"db/lookup.rkt"
that uses helper modules "db/barcodes.rkt"
and
"db/makers.rkt"
. Similarly, the sorting-machine driver
"machine/control.rkt"
might use helper modules "machine/sensors.rkt"
and "machine/actuators.rkt"
.
#
The "sort.rkt"
module uses the relative paths "db/lookup.rkt"
and
"machine/control.rkt"
to import from the database and machine-control
libraries:
"sort.rkt"
#lang racket
(require "db/lookup.rkt" "machine/control.rkt")
....
The "db/lookup.rkt"
module similarly uses paths relative to its own
source to access the "db/barcodes.rkt"
and "db/makers.rkt"
modules:
"db/lookup.rkt"
#lang racket
(require "barcode.rkt" "makers.rkt")
....
Ditto for "machine/control.rkt"
:
"machine/control.rkt"
#lang racket
(require "sensors.rkt" "actuators.rkt")
....
Racket tools all work automatically with relative paths. For example,
racket sort.rkt
on the command line runs the "sort.rkt"
program and automatically
loads and compiles required modules. With a large enough program,
compilation from source can take too long, so use
raco make sort.rkt
See [missing] for more information on
raco make
.
to compile "sort.rkt"
and all its dependencies to bytecode files.
Running racket sort.rkt
will automatically use bytecode files when
they are present.
1.2. Library Collections
A collection is a hierarchical grouping of installed library modules.
A module in a collection is referenced through an unquoted, suffixless
path. For example, the following module refers to the "date.rkt"
library that is part of the "racket"
collection:
#lang racket
(require racket/date)
(printf "Today is ~s\n"
(date->string (seconds->date (current-seconds))))
When you search the online Racket documentation, the search results indicate the module that provides each binding. Alternatively, if you reach a binding’s documentation by clicking on hyperlinks, you can hover over the binding name to find out which modules provide it.
A module reference like racket/date
looks like an identifier, but it
is not treated in the same way as printf
or date->string
. Instead,
when require
sees a module reference that is unquoted, it converts the
reference to a collection-based module path:
-
First, if the unquoted path contains no
/
, thenrequire
automatically adds a"/main"
to the reference. For example,(require slideshow)
is equivalent to(require slideshow/main)
. -
Second,
require
implicitly adds a".rkt"
suffix to the path. -
Finally,
require
resolves the path by searching among installed collections, instead of treating the path as relative to the enclosing module’s path.
To a first approximation, a collection is implemented as a filesystem
directory. For example, the "racket"
collection is mostly located in a
"racket"
directory within the Racket installation’s "collects"
directory, as reported by
#lang racket
(require setup/dirs)
(build-path (find-collects-dir) ; main collection directory
"racket")
The Racket installation’s "collects"
directory, however, is only one
place that require
looks for collection directories. Other places
include the user-specific directory reported by
(find-user-collects-dir)
and directories configured through the
PLTCOLLECTS
search path. Finally, and most typically, collections are
found through installed packages.
1.3. Packages and Collections
A package is a set of libraries that are installed through the Racket
package manager (or included as pre-installed in a Racket
distribution). For example, the racket/gui
library is provided by the
"gui"
package, while parser-tools/lex
is provided by the
"parser-tools"
library.
More precisely,
racket/gui
is provided by"gui-lib"
,parser-tools/lex
is provided by"parser-tools-lib"
, and the"gui"
and"parser-tools"
packages extend"gui-lib"
and"parser-tools-lib"
with documentation.
Racket programs do not refer to packages directly. Instead, programs refer to libraries via collections, and adding or removing a package changes the set of collection-based libraries that are available. A single package can supply libraries in multiple collections, and two different packages can supply libraries in the same collection (but not the same libraries, and the package manager ensures that installed packages do not conflict at that level).
For more information about packages, see [missing].
1.4. Adding Collections
Looking back at the candy-sorting example of Organizing Modules, suppose
that modules in "db/"
and "machine/"
need a common set of helper
functions. Helper functions could be put in a "utils/"
directory, and
modules in "db/"
or "machine/"
could access utility modules with
relative paths that start "../utils/"
. As long as a set of modules
work together in a single project, it’s best to stick with relative
paths. A programmer can follow relative-path references without knowing
about your Racket configuration.
Some libraries are meant to be used across multiple projects, so that keeping the library source in a directory with its uses does not make sense. In that case, the best option is add a new collection. After the library is in a collection, it can be referenced with an unquoted path, just like libraries that are included with the Racket distribution.
You could add a new collection by placing files in the Racket
installation or one of the directories reported by
(get-collects-search-dirs)
. Alternatively, you could add to the list
of searched directories by setting the PLTCOLLECTS
environment
variable.If you set PLTCOLLECTS
, include an empty path in by starting
the value with a colon Unix and Mac OS
or semicolon Windows
so
that the original search paths are preserved. The best option, however,
is to add a package.
Creating a package does not mean that you have to register with a package server or perform a bundling step that copies your source code into an archive format. Creating a package can simply mean using the package manager to make your libraries locally accessible as a collection from their current source locations.
For example, suppose you have a directory "/usr/molly/bakery"
that
contains the "cake.rkt"
module from the beginning of this section
and other related modules. To make the modules available as a "bakery"
collection, either
-
Use the
raco pkg
command-line tool:raco pkg install --link /usr/molly/bakery
where the
--link
flag is not actually needed when the provided path includes a directory separator. -
Use DrRacket’s Package Manager item from the File menu. In the Do What I Mean panel, click Browse..., choose the
"/usr/molly/bakery"
directory, and click Install.
Afterward, (require bakery/cake)
from any module will import the
print-cake
function from "/usr/molly/bakery/cake.rkt"
.
By default, the name of the directory that you install is used both as the package name and as the collection that is provided by the package. Also, the package manager normally defaults to installation only for the current user, as opposed to all users of a Racket installation. See
missing
If you intend to distribute your libraries to others, choose collection
and package names carefully. The collection namespace is hierarchical,
but top-level collection names are global, and the package namespace is
flat. Consider putting one-off libraries under some top-level name like
"molly"
that identifies the producer. Use a collection name like
"bakery"
when producing the definitive collection of baked-goods
libraries.
After your libraries are put in a collection you can still use raco make
to compile the library sources, but it’s better and more
convenient to use raco setup
. The raco setup
command takes a
collection name as opposed to a file name
and compiles all libraries
within the collection. In addition, raco setup
can build documentation
for the collection and add it to the documentation index, as specified
by a "info.rkt"
module in the collection. See [missing] for more
information on raco setup
.
2. Module Syntax
The #lang
at the start of a module file begins a shorthand for a
module
form, much like '
is a shorthand for a quote
form. Unlike
'
, the #lang
shorthand does not work well in a REPL, in part because
it must be terminated by an end-of-file, but also because the longhand
expansion of #lang
depends on the name of the enclosing file.
2.1. The module
Form
The longhand form of a module declaration, which works in a REPL as well as a file, is
(module name-id initial-module-path
decl ...)
where the name-id
is a name for the module, initial-module-path
is
an initial import, and each decl
is an import, export, definition, or
expression. In the case of a file, name-id
normally matches the name
of the containing file, minus its directory path or file extension, but
name-id
is ignored when the module is require
d through its file’s
path.
The initial-module-path
is needed because even the require
form must
be imported for further use in the module body. In other words, the
initial-module-path
import bootstraps the syntax that is available in
the body. The most commonly used initial-module-path
is racket
,
which supplies most of the bindings described in this guide, including
require
, define
, and provide
. Another commonly used
initial-module-path
is racket/base
, which provides less
functionality, but still much of the most commonly needed functions and
syntax.
For example, the "cake.rkt"
example of the previous section could be
written as
(module cake racket
(provide print-cake)
(define (print-cake n)
(show " ~a " n #\.)
(show " .-~a-. " n #\|)
(show " | ~a | " n #\space)
(show "---~a---" n #\-))
(define (show fmt n ch)
(printf fmt (make-string n ch))
(newline)))
Furthermore, this module
form can be evaluated in a REPL to declare a
cake
module that is not associated with any file. To refer to such an
unassociated module, quote the module name:
Examples:
> (require 'cake)
> (print-cake 3)
...
.-|||-.
| |
---------
Declaring a module does not immediately evaluate the body definitions
and expressions of the module. The module must be explicitly require
d
at the top level to trigger evaluation. After evaluation is triggered
once, later require
s do not re-evaluate the module body.
Examples:
> (module hi racket
(printf "Hello\n"))
> (require 'hi)
Hello
> (require 'hi)
2.2. The #lang
Shorthand
The body of a #lang
shorthand has no specific syntax, because the
syntax is determined by the language name that follows #lang
.
In the case of #lang
racket
, the syntax is
#lang racket
decl ...
which reads the same as
(module name racket
decl ...)
where name
is derived from the name of the file that contains the
#lang
form.
The #lang
racket/base
form has the same syntax as #lang
racket
,
except that the longhand expansion uses racket/base
instead of
racket
. The #lang
scribble/manual
form, in contrast, has a
completely different syntax that doesn’t even look like Racket, and
which we do not attempt to describe in this guide.
Unless otherwise specified, a module that is documented as a “language”
using the #lang
notation will expand to module
in the same way as
#lang
racket
. The documented language name can be used directly with
module
or require
, too.
2.3. Submodules
A module
form can be nested within a module, in which case the nested
module
form declares a submodule. Submodules can be referenced
directly by the enclosing module using a quoted name. The following
example prints "Tony"
by importing tiger
from the zoo
submodule:
"park.rkt"
#lang racket
(module zoo racket
(provide tiger)
(define tiger "Tony"))
(require 'zoo)
tiger
Running a module does not necessarily run its submodules. In the above
example, running "park.rkt"
runs its submodule zoo
only because the
"park.rkt"
module require
s the zoo
submodule. Otherwise, a module
and each of its submodules can be run independently. Furthermore, if
"park.rkt"
is compiled to a bytecode file via `raco make`
, then
the code for "park.rkt"
or the code for zoo
can be loaded
independently.
Submodules can be nested within submodules, and a submodule can be referenced directly by a module other than its enclosing module by using a submodule path.
A module*
form is similar to a nested module
form:
(module* name-id initial-module-path-or-#f
decl ...)
The module*
form differs from module
in that it inverts the
possibilities for reference between the submodule and enclosing module:
-
A submodule declared with
module
can berequire
d by its enclosing module, but the submodule cannotrequire
the enclosing module or lexically reference the enclosing module’s bindings. -
A submodule declared with
module*
canrequire
its enclosing module, but the enclosing module cannotrequire
the submodule.
In addition, a module*
form can specify #f
in place of an
initial-module-path
, in which case the submodule sees all of the
enclosing module’s bindings—including bindings that are not exported via
provide
.
One use of submodules declared with module*
and #f
is to export
additional bindings through a submodule that are not normally exported
from the module:
"cake.rkt"
#lang racket
(provide print-cake)
(define (print-cake n)
(show " ~a " n #\.)
(show " .-~a-. " n #\|)
(show " | ~a | " n #\space)
(show "---~a---" n #\-))
(define (show fmt n ch)
(printf fmt (make-string n ch))
(newline))
(module* extras #f
(provide show))
In this revised "cake.rkt"
module, show
is not imported by a module
that uses (require "cake.rkt")
, since most clients of "cake.rkt"
will not want the extra function. A module can require the extra
submodule using (require (submod "cake.rkt" extras))
to access the
otherwise hidden show
function.See submodule paths for more
information on submod
.
2.4. Main and Test Submodules
The following variant of "cake.rkt"
includes a main
submodule that
calls print-cake
:
"cake.rkt"
#lang racket
(define (print-cake n)
(show " ~a " n #\.)
(show " .-~a-. " n #\|)
(show " | ~a | " n #\space)
(show "---~a---" n #\-))
(define (show fmt n ch)
(printf fmt (make-string n ch))
(newline))
(module* main #f
(print-cake 10))
Running a module does not run its module*
-defined submodules.
Nevertheless, running the above module via racket
or DrRacket prints a
cake with 10 candles, because the main
submodule is a special case.
When a module is provided as a program name to the racket
executable
or run directly within DrRacket, if the module has a main
submodule,
the main
submodule is run after its enclosing module. Declaring a
main
submodule thus specifies extra actions to be performed when a
module is run directly, instead of require
d as a library within a
larger program.
A main
submodule does not have to be declared with module*
. If the
main
module does not need to use bindings from its enclosing module,
it can be declared with module
. More commonly, main
is declared
using module+
:
(module+ name-id
decl ...)
A submodule declared with module+
is like one declared with module*
using #f
as its initial-module-path
. In addition, multiple
module+
forms can specify the same submodule name, in which case the
bodies of the module+
forms are combined to create a single submodule.
The combining behavior of module+
is particularly useful for defining
a test
submodule, which can be conveniently run using raco test
in
much the same way that main
is conveniently run with racket
. For
example, the following "physics.rkt"
module exports drop
and
to-energy
functions, and it defines a test
module to hold unit
tests:
"physics.rkt"
#lang racket
(module+ test
(require rackunit)
(define ε 1e-10))
(provide drop
to-energy)
(define (drop t)
(* 1/2 9.8 t t))
(module+ test
(check-= (drop 0) 0 ε)
(check-= (drop 10) 490 ε))
(define (to-energy m)
(* m (expt 299792458.0 2)))
(module+ test
(check-= (to-energy 0) 0 ε)
(check-= (to-energy 1) 9e+16 1e+15))
Importing "physics.rkt"
into a larger program does not run the drop
and to-energy
tests—or even trigger the loading of the test code, if
the module is compiled—but running raco test physics.rkt
at a command
line runs the tests.
The above "physics.rkt"
module is equivalent to using module*
:
"physics.rkt"
#lang racket
(provide drop
to-energy)
(define (drop t)
(* 1/2 49/5 t t))
(define (to-energy m)
(* m (expt 299792458 2)))
(module* test #f
(require rackunit)
(define ε 1e-10)
(check-= (drop 0) 0 ε)
(check-= (drop 10) 490 ε)
(check-= (to-energy 0) 0 ε)
(check-= (to-energy 1) 9e+16 1e+15))
Using module+
instead of module*
allows tests to be interleaved with
function definitions.
The combining behavior of module+
is also sometimes helpful for a
main
module. Even when combining is not needed, (module+ main ....)
is preferred as it is more readable than (module* main #f ....)
.
3. Module Paths
A module path is a reference to a module, as used with require
or as
the initial-module-path
in a module
form. It can be any of several
forms:
(quote id)
A module path that is a quoted identifier refers to a non-file module
declaration using the identifier. This form of module reference makes
the most sense in a REPL.
Examples:
> (module m racket
(provide color)
(define color "blue"))
> (module n racket
(require 'm)
(printf "my favorite color is ~a\n" color))
> (require 'n)
my favorite color is blue
rel-string
A string module path is a relative path using Unix-style conventions:
/
is the path separator, ..
refers to the parent directory, and .
refers to the same directory. The rel-string
must not start or end
with a path separator. If the path has no suffix, ".rkt"
is added
automatically.
The path is relative to the enclosing file, if any, or it is relative to
the current directory. (More precisely, the path is relative to the
value of (current-load-relative-directory)
, which is set while loading
a file.)
Module Basics shows examples using relative paths.
If a relative path ends with a ".ss"
suffix, it is converted to
".rkt"
. If the file that implements the referenced module actually
ends in ".ss"
, the suffix will be changed back when attempting to load
the file but a `".rkt"` suffix takes precedence
. This two-way
conversion provides compatibility with older versions of Racket.
id
A module path that is an unquoted identifier refers to an installed
library. The id
is constrained to contain only ASCII letters, ASCII
numbers, +
, -
, _
, and /
, where /
separates path elements
within the identifier. The elements refer to collections and
sub-collections, instead of directories and sub-directories.
An example of this form is racket/date
. It refers to the module whose
source is the "date.rkt"
file in the "racket"
collection, which is
installed as part of Racket. The ".rkt"
suffix is added automatically.
Another example of this form is racket
, which is commonly used at the
initial import. The path racket
is shorthand for racket/main
; when
an id
has no /
, then /main
is automatically added to the end.
Thus, racket
or racket/main
refers to the module whose source is the
"main.rkt"
file in the "racket"
collection.
Examples:
> (module m racket
(require racket/date)
(printf "Today is ~s\n"
(date->string (seconds->date (current-seconds)))))
> (require 'm)
Today is "Monday, January 21st, 2019"
When the full path of a module ends with ".rkt"
, if no such file
exists but one does exist with the ".ss"
suffix, then the ".ss"
suffix is substituted automatically. This transformation provides
compatibility with older versions of Racket.
(lib rel-string)
Like an unquoted-identifier path, but expressed as a string instead of
an identifier. Also, the rel-string
can end with a file suffix, in
which case ".rkt"
is not automatically added.
Example of this form include (lib "racket/date.rkt")
and (lib "racket/date")
, which are equivalent to racket/date
. Other examples
include (lib "racket")
, (lib "racket/main")
, and (lib "racket/main.rkt")
, which are all equivalent to racket
.
Examples:
> (module m (lib "racket")
(require (lib "racket/date.rkt"))
(printf "Today is ~s\n"
(date->string (seconds->date (current-seconds)))))
> (require 'm)
Today is "Monday, January 21st, 2019"
(planet id)
Accesses a third-party library that is distributed through the PLaneT
server. The library is downloaded the first time that it is needed, and
then the local copy is used afterward.
The id
encodes several pieces of information separated by a /
: the
package owner, then package name with optional version information, and
an optional path to a specific library with the package. Like id
as
shorthand for a lib
path, a ".rkt"
suffix is added automatically,
and /main
is used as the path if no sub-path element is supplied.
Examples:
> (module m (lib "racket")
; Use "schematics"'s "random.plt" 1.0, file "random.rkt":
(require (planet schematics/random:1/random))
(display (random-gaussian)))
> (require 'm)
0.9050686838895684
As with other forms, an implementation file ending with ".ss"
can be
substituted automatically if no implementation file ending with ".rkt"
exists.
(planet package-string)
Like the symbol form of a planet
, but using a string instead of an
identifier. Also, the package-string
can end with a file suffix, in
which case ".rkt"
is not added.
As with other forms, an ".ss"
extension is converted to ".rkt"
,
while an implementation file ending with ".ss"
can be substituted
automatically if no implementation file ending with ".rkt"
exists.
(planet rel-string (user-string pkg-string vers ...))
vers = nat
| (nat nat)
| (= nat)
| (+ nat)
| (- nat)
A more general form to access a library from the PLaneT server. In this
general form, a PLaneT reference starts like a lib
reference with a
relative path, but the path is followed by information about the
producer, package, and version of the library. The specified package is
downloaded and installed on demand.
The vers
es specify a constraint on the acceptable version of the
package, where a version number is a sequence of non-negative integers,
and the constraints determine the allowable values for each element in
the sequence. If no constraint is provided for a particular element,
then any version is allowed; in particular, omitting all vers
es means
that any version is acceptable. Specifying at least one vers
is
strongly recommended.
For a version constraint, a plain nat
is the same as (+ nat)
, which
matches nat
or higher for the corresponding element of the version
number. A (start-nat end-nat)
matches any number in the range
start-nat
to end-nat
, inclusive. A (= nat)
matches only exactly
nat
. A (- nat)
matches nat
or lower.
Examples:
> (module m (lib "racket")
(require (planet "random.rkt" ("schematics" "random.plt" 1 0)))
(display (random-gaussian)))
> (require 'm)
0.9050686838895684
The automatic ".ss"
and ".rkt"
conversions apply as with other
forms.
(file string)
Refers to a file, where string
is a relative or absolute path using
the current platform’s conventions. This form is not portable, and it
should not be used when a plain, portable rel-string
suffices.
The automatic ".ss"
and ".rkt"
conversions apply as with other
forms.
(submod base element ...+)
base = module-path
| "."
| ".."
element = id
| ".."
Refers to a submodule of base
. The sequence of element
s within
submod
specify a path of submodule names to reach the final submodule.
Examples:
> (module zoo racket
(module monkey-house racket
(provide monkey)
(define monkey "Curious George")))
> (require (submod 'zoo monkey-house))
> monkey
"Curious George"
Using "."
as base
within submod
stands for the enclosing module.
Using ".."
as base
is equivalent to using "."
followed by an extra
".."
. When a path of the form (quote id)
refers to a submodule, it
is equivalent to (submod "." id)
.
Using ".."
as an element
cancels one submodule step, effectively
referring to the enclosing module. For example, (submod "..")
refers
to the enclosing module of the submodule in which the path appears.
Examples:
> (module zoo racket
(module monkey-house racket
(provide monkey)
(define monkey "Curious George"))
(module crocodile-house racket
(require (submod ".." monkey-house))
(provide dinner)
(define dinner monkey)))
> (require (submod 'zoo crocodile-house))
> dinner
"Curious George"
4. Imports: require
The require
form imports from another module. A require
form can
appear within a module, in which case it introduces bindings from the
specified module into importing module. A require
form can also appear
at the top level, in which case it both imports bindings and
instantiates the specified module; that is, it evaluates the body
definitions and expressions of the specified module, if they have not
been evaluated already.
A single require
can specify multiple imports at once:
(require require-spec ...)
Specifying multiple require-spec
s in a single require
is essentially
the same as using multiple require
s, each with a single
require-spec
. The difference is minor, and confined to the top-level:
a single require
can import a given identifier at most once, whereas a
separate require
can replace the bindings of a previous require
both only at the top level, outside of a module
.
The allowed shape of a require-spec
is defined recursively:
module-path
In its simplest form, a require-spec
is a module-path
(as defined
in the previous section, Module Paths). In this case, the bindings
introduced by require
are determined by provide
declarations within
each module referenced by each module-path
.
Examples:
> (module m racket
(provide color)
(define color "blue"))
> (module n racket
(provide size)
(define size 17))
> (require 'm 'n)
> (list color size)
'("blue" 17)
(only-in require-spec id-maybe-renamed ...)
id-maybe-renamed = id
| [orig-id bind-id]
An only-in
form limits the set of bindings that would be introduced by
a base require-spec
. Also, only-in
optionally renames each binding
that is preserved: in a [orig-id bind-id]
form, the orig-id
refers
to a binding implied by require-spec
, and bind-id
is the name that
will be bound in the importing context instead of orig-id
.
Examples:
> (module m (lib "racket")
(provide tastes-great?
less-filling?)
(define tastes-great? #t)
(define less-filling? #t))
> (require (only-in 'm tastes-great?))
> tastes-great?
#t
> less-filling?
less-filling?: undefined;
cannot reference an identifier before its definition
in module: top-level
> (require (only-in 'm [less-filling? lite?]))
> lite?
#t
(except-in require-spec id ...)
This form is the complement of only-in
: it excludes specific bindings
from the set specified by require-spec
.
(rename-in require-spec [orig-id bind-id] ...)
This form supports renaming like only-in
, but leaving alone
identifiers from require-spec
that are not mentioned as an orig-id
.
(prefix-in prefix-id require-spec)
This is a shorthand for renaming, where prefix-id
is added to the
front of each identifier specified by require-spec
.
The only-in
, except-in
, rename-in
, and prefix-in
forms can be
nested to implement more complex manipulations of imported bindings. For
example,
(require
(prefix-in
m:
(except-in
'm
ghost)))
imports all bindings that m
exports, except for the ghost
binding,
and with local names that are prefixed with m:
.
Equivalently, the prefix-in
could be applied before except-in
, as
long as the omission with except-in
is specified using the m:
prefix:
(require
(except-in
(prefix-in
m:
'm)
m:ghost))
5. Exports: provide
By default, all of a module’s definitions are private to the module. The
provide
form specifies definitions to be made available where the
module is require
d.
(provide provide-spec ...)
A provide
form can only appear at module level (i.e., in the
immediate body of a module
). Specifying multiple provide-spec
s in
a single provide
is exactly the same as using multiple provide
s each
with a single provide-spec
.
Each identifier can be exported at most once from a module across all
provide
s within the module. More precisely, the external name for each
export must be distinct; the same internal binding can be exported
multiple times with different external names.
The allowed shape of a provide-spec
is defined recursively:
identifier
In its simplest form, a provide-spec
indicates a binding within its
module to be exported. The binding can be from either a local
definition, or from an import.
(rename-out [orig-id export-id] ...)
A rename-out
form is similar to just specifying an identifier, but the
exported binding orig-id
is given a different name, export-id
, to
importing modules.
(struct-out struct-id)
A struct-out
form exports the bindings created by (struct struct-id ....)
.
+See [missing] for information on
define-struct
.
(all-defined-out)
The all-defined-out
shorthand exports all bindings that are defined
within the exporting module as opposed to imported
.
Use of the all-defined-out
shorthand is generally discouraged, because
it makes less clear the actual exports for a module, and because Racket
programmers get into the habit of thinking that definitions can be added
freely to a module without affecting its public interface (which is not
the case when all-defined-out
is used).
(all-from-out module-path)
The all-from-out
shorthand exports all bindings in the module that
were imported using a require-spec
that is based on module-path
.
Although different module-path
s could refer to the same file-based
module, re-exporting with all-from-out
is based specifically on the
module-path
reference, and not the module that is actually referenced.
(except-out provide-spec id ...)
Like provide-spec
, but omitting the export of each id
, where id
is
the external name of the binding to omit.
(prefix-out prefix-id provide-spec)
Like provide-spec
, but adding prefix-id
to the beginning of the
external name for each exported binding.
6. Assignment and Redefinition
The use of set!
on variables defined within a module is limited to the
body of the defining module. That is, a module is allowed to change the
value of its own definitions, and such changes are visible to importing
modules. However, an importing context is not allowed to change the
value of an imported binding.
Examples:
> (module m racket
(provide counter increment!)
(define counter 0)
(define (increment!)
(set! counter (add1 counter))))
> (require 'm)
> counter
0
> (increment!)
> counter
1
> (set! counter -1)
set!: cannot mutate module-required identifier
at: counter
in: (set! counter -1)
As the above example illustrates, a module can always grant others the
ability to change its exports by providing a mutator function, such as
increment!
.
The prohibition on assignment of imported variables helps support modular reasoning about programs. For example, in the module,
(module m racket
(provide rx:fish fishy-string?)
(define rx:fish #rx"fish")
(define (fishy-string? s)
(regexp-match? rx:fish s)))
the function fishy-string?
will always match strings that contain
“fish”, no matter how other modules use the rx:fish
binding. For
essentially the same reason that it helps programmers, the prohibition
on assignment to imports also allows many programs to be executed more
efficiently.
Along the same lines, when a module contains no set!
of a particular
identifier that is defined within the module, then the identifier is
considered a constant that cannot be changed—not even by re-declaring
the module.
Consequently, re-declaration of a module is not generally allowed. For file-based modules, simply changing the file does not lead to a re-declaration in any case, because file-based modules are loaded on demand, and the previously loaded declarations satisfy future requests. It is possible to use Racket’s reflection support to re-declare a module, however, and non-file modules can be re-declared in the REPL; in such cases, the re-declaration may fail if it involves the re-definition of a previously constant binding.
> (module m racket
(define pie 3.141597))
> (require 'm)
> (module m racket
(define pie 3))
define-values: assignment disallowed;
cannot re-define a constant
constant: pie
in module: 'm
For exploration and debugging purposes, the Racket reflective layer
provides a compile-enforce-module-constants
parameter to disable the
enforcement of constants.
> (compile-enforce-module-constants #f)
> (module m2 racket
(provide pie)
(define pie 3.141597))
> (require 'm2)
> (module m2 racket
(provide pie)
(define pie 3))
> (compile-enforce-module-constants #t)
> pie
3
7. Modules and Macros
Racket’s module system cooperates closely with Racket’s macro system for
adding new syntactic forms to Racket. For example, in the same way that
importing racket/base
introduces syntax for require
and lambda
,
importing other modules can introduce new syntactic forms (in addition
to more traditional kinds of imports, such as functions or constants).
We introduce macros in more detail later, in [missing], but here’s a simple example of a module that defines a pattern-based macro:
(module noisy racket
(provide define-noisy)
(define-syntax-rule (define-noisy (id arg ...) body)
(define (id arg ...)
(show-arguments 'id (list arg ...))
body))
(define (show-arguments name args)
(printf "calling ~s with arguments ~e" name args)))
The define-noisy
binding provided by this module is a macro that acts
like define
for a function, but it causes each call to the function to
print the arguments that are provided to the function:
> (require 'noisy)
> (define-noisy (f x y)
(+ x y))
> (f 1 2)
calling f with arguments '(1 2)
3
Roughly, the define-noisy
form works by replacing
(define-noisy (f x y)
(+ x y))
with
(define (f x y)
(show-arguments 'f (list x y))
(+ x y))
Since show-arguments
isn’t provided by the noisy
module, however,
this literal textual replacement is not quite right. The actual
replacement correctly tracks the origin of identifiers like
show-arguments
, so they can refer to other definitions in the place
where the macro is defined—even if those identifiers are not available
at the place where the macro is used.
There’s more to the macro and module interaction than identifier
binding. The define-syntax-rule
form is itself a macro, and it expands
to compile-time code that implements the transformation from
define-noisy
into define
. The module system keeps track of which
code needs to run at compile and which needs to run normally, as
explained more in [missing] and [missing].